Atrial Natriuretic Peptide Inhibits Evoked Catecholamine Release by Altering Sensitivity to Calcium

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Vol. 283, Issue 2, 426-433, 1997

Atrial Natriuretic Peptide Inhibits Evoked Catecholamine Release by Altering Sensitivity to Calcium¹

S. Kanwal, B. J. Elmquist and G. J. Trachte

Department of Pharmacology, School of Medicine, University of Minnesota-Duluth Duluth, Minnesota

	Abstract

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Natriuretic peptides are cyclized peptides produced by cardiovascular and neural tissues. These peptides inhibit various secretoryresponses such as the release of renin, aldosterone and autonomicneurotransmitters. This report tests the hypothesis that atrialnatriuretic peptide reduces dopamine efflux from an adrenergiccell line, rat pheochromocytoma cells, by suppressing intracellularcalcium concentrations. The L-type calcium channel inhibitor,nifedipine, markedly suppressed dopamine release from depolarizedPC12 cells, suggesting that calcium entering through this channelwas the predominant stimulus for dopamine efflux. Atrial natriureticpeptide maximally reduced depolarization-evoked dopamine release20 ± 3% at a concentration of 100 nM and this effect was abolishedby nifedipine, but not by pretreatment with the N-type calciumchannel inhibitor, $omega$ -conotoxin, or an inhibitor of calcium-inducedcalcium release, ryanodine. In cells loaded with Fura-2, atrialnatriuretic peptide both augmented depolarization-induced increasesof intracellular free calcium concentrations and accelerated thedepolarization-induced quenching of the Fura-2 signal by manganese,findings consistent with enhanced conductivity of calcium channels.Dopamine efflux induced by either the calcium ionophore, A23187,or staphylococcal $alpha$ toxin was attenuated by atrial natriureticpeptide. Additionally, a natriuretic peptide interacting solelywith the natriuretic peptide C receptor in these cells, C-typenatriuretic peptide, also suppressed calcium-induced dopamineefflux in permeabilized cells. These data are consistent withnatriuretic peptides attenuating catecholamine exocytosis in responseto calcium but inconsistent with the neuromodulatory effect resultingfrom a reduction in intracellular calcium concentrations withinpheochromocytoma cells.

	Introduction

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Atrial natriuretic peptide, the first member of the natriuretic peptide family to be identified (de Bold et al., 1981), affectscardiovascular homeostasis by promoting diuresis, natriuresisand vasodilation, and by reducing both aldosterone secretion (Atlasand Maack, 1987) and adrenergic neurotransmitter release (Debinskiet al., 1990). The inhibitory effects of atrial natriuretic peptideon adrenergic neurotransmission have been reported in rat isolatedmesenteric arteries (Nakamaru and Inagami, 1986), rabbit isolatedvasa deferentia (Drewett et al., 1989a), bovine adrenal chromaffincells (Babinski et al., 1995), the rat hypothalamus (Giridharet al., 1992) and nerve growth factor-treated PC12 cells (Drewettet al., 1988). This inhibition of adrenergic neurotransmission,although widely observed, has not been explained mechanistically.We attempt to resolve the mechanism of natriuretic peptide neuromodulationby defining the following: 1) the calcium components accountingfor neurotransmitter release from PC12 cells; 2) the involvementof the various calcium channels in neuromodulatory effects ofatrial natriuretic peptides; 3) the influence of atrial natriureticpeptide on calcium homeostasis in depolarized cells; 4) the influenceof atrial natriuretic peptide on the sensitivity of the exocytoticprocess to calcium and 5) the effect of a selective ligand fornatriuretic peptide C receptors on exocytosis of dopamine in responseto calcium.

Because calcium is typically the stimulus for neurotransmitter release from neurons (Kelly et al., 1979), initial experimentssought to identify the calcium channel promoting neurotransmitterrelease in response to a depolarizing stimulus. We then testedthe involvement of various calcium channels in neuromodulatoryeffects of natriuretic peptides by observing whether natriureticpeptide effects were sustained in the presence of selective calciumchannel antagonists. The last group of experiments examined whetheratrial natriuretic peptide attenuates catecholamine release inresponse to a depolarizing stimulus by suppressing either calciumentry into the cells or calcium effects on exocytosis. A suppressionof calcium entry should be evidenced by reductions in both calciumconductance and intracellular calcium concentrations. Alternatively,a decreased sensitivity of dopamine exocytosis to calcium shouldbe indicated by an attenuation of dopamine release in cells permeabilizedto calcium. Natriuretic peptides have been demonstrated to reduceintracellular calcium concentrations (Hassid, 1986; Cornwell andLincoln, 1988; Barrett et al., 1991; Nascimento-Gomes et al.,1995), calcium conductance (Gisbert and Fischmeister, 1988; Sorberaand Morad, 1990; Pella, 1991; Le Grand et al., 1992; White etal., 1993) and calcium fluxes in a variety of cell types (Chiuet al., 1986). Natriuretic peptides also suppress calcium concentrationsin vascular smooth muscle by augmenting a calcium pump extrudingcalcium (Furukawa et al., 1988). In contrast, natriuretic peptidesaugment L-type calcium channel conductance (McCarthy et al., 1990;Dai and Quamme, 1993) and suppress calcium-induced aldosteroneproduction from adrenal glomerulosa cells (Lotshaw et al., 1991).Furthermore, the potentiative effect of natriuretic peptides oncalcium conductance appeared to be mediated by the natriureticpeptide C receptor (Isales et al., 1992), whereas the inhibitoryeffect was mediated by a different natriuretic peptide receptorthat elevated guanylyl cyclase activity (Oda et al., 1992). Themajority of these studies examining natriuretic peptide effectson calcium homeostasis find an inhibitory effect on intracellularcalcium concentrations. The exception to this generalization occursin the adrenal glomerulosa, where natriuretic peptides attenuatecalcium effects to augment aldosterone synthesis (Lotshaw et al.,1991). Our study defines atrial natriuretic peptide effects oncalcium concentrations, calcium conductance and the calcium sensitivityof neurotransmitter exocytosis in PC12 cells and the relevanceof these actions to neuromodulatory effects of natriuretic peptides.

	Materials and Methods

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Cell culture. PC12 cells were subcultured in 25-cm³ flasks or 25-mm coverslips coated with rat tail collagen and bathed in Dulbecco's modifiedEagles medium supplemented with 10% fetal calf serum and 5% heatinactivated horse serum. Cells were plated at a density of 6 ×10⁵ per 25-cm³ culture flask for catecholamine release experiments and 3.6 ×10⁵ cells per coverslip for measurement of intracellular free calciumconcentration. After 24 hr, the growth media was replaced by differentiatingmedia consisting of Dulbecco's modified Eagles medium containing200 ng/ml 7S-nerve growth factor and 1% fetal calf serum. Cellswere allowed to differentiate over a period of 8 to 10 days inan incubator at 37°C and an atmosphere containing 5% CO₂. Cellsreceived fresh differentiating media every 3 days. Cells frompassages 18 to 35 were used for experiments.

Catecholamine release and measurement. Catecholamine release was induced by exposure to either high potassium chloride concentrations (40 mM), caffeine (40 mM),the calcium ionophore, A23187 (10 µM) or staphylococcal $alpha$ toxin(100 U/ml), in the presence of 2 mM extracellular calcium concentrations.The high potassium buffer contained 76 mM NaCl, 40 mM KCl, 25mM NaHCO₃, 1.2 mM NaH₂PO₄, 0.5 mM MgCl₂, 2 mM CaCl₂ and 10 mMglucose. Catecholamines were measured by high performance liquidchromotography with electrochemical detection, as previously described(Trachte et al., 1995). The participation of the various calciumchannels in mediating catecholamine release in response to thehigh potassium buffer was assessed using either the L-type calciumchannel inhibitor, nifedipine (20 nM), or an inhibitor of N-typecalcium channels, $omega$ -conotoxin (500 nM). The contribution of calciumreleased from the intracellular ryanodine-sensitive calcium storetoward catecholamine release was assessed by the ability of ryanodine(10 µM) to block catecholamine secretion. The importance of extracellularcalcium in inducing dopamine efflux was defined by eliminatingcalcium from the high potassium buffer and substituting 2 mM EGTA.Nifedipine was dissolved in 95% alcohol and diluted in Krebs-bicarbonatebuffer. $omega$ -Conotoxin and ryanodine were dissolved and diluted inKrebs-bicarbonate buffer. This buffer was identical to the highpotassium buffer except that the concentration of sodium chloridewas adjusted to 112 mM, and that of potassium chloride, to 4.5mM. Cells were pretreated with nifedipine, $omega$ -conotoxin or ryanodinefor 5 min before treatment with the high potassium buffer. Themedium then was discarded and each flask was treated with thehigh potassium buffer in the presence of the above test agentsor their vehicles for 5 min. The effectiveness of ryanodine wasascertained by its ability to block dopamine efflux promoted bycaffeine (40 mM).

The effect of atrial natriuretic peptide on high potassium-induced catecholamine release was examined by exposing each cultureto the high potassium buffer plus atrial natriuretic peptide concentrationsof 1, 10 or 100 nM or the atrial natriuretic peptide diluent (Krebs-bicarbonatebuffer). The involvement of calcium channels or the intracellularryanodine-sensitive calcium pool in natriuretic peptide effectson high potassium-induced catecholamine release was assessed byrepeating the above experimental sequence in cultures pretreatedwith nifedipine, $omega$ -conotoxin or ryanodine for 5 min and thesetest agents were also present in the high potassium buffer duringthe 5-min treatment period.

The influence of natriuretic peptides on exocytosis induced by calcium was assessed using either the calcium ionophore, A23187(10 µM), or the membrane permeabilizing agent, staphylococcal $alpha$ toxin (100 units/ml in a final volume of 3 ml), in the presenceof 2 mM calcium. A23187 was dissolved in dimethyl sulfoxide anddiluted in Krebs-bicarbonate buffer. Cultures were treated withKrebs-bicarbonate buffer containing A23187 and either the natriureticpeptide vehicle (Krebs-bicarbonate buffer) or one of the threeconcentrations of atrial natriuretic peptide (0.1-10 nM). Staphylococcal $alpha$ toxin was dissolved in distilled water and diluted in calcium-freeKrebs-bicarbonate buffer to achieve a final concentration of 100units/ml. Calcium-free Krebs-bicarbonate buffer was prepared byexcluding CaCl₂ and chelating residual calcium with 4 mM EGTA.Cells were exposed to calcium-free buffer containing staphylococcal $alpha$ toxin for 30 min. The medium then was discarded and each flaskwas treated with Krebs-bicarbonate buffer containing 2 mM CaCl₂and either the atrial natriuretic peptide vehicle or one of thethree concentrations of atrial natriuretic peptide (0.1-10 nM)for 5 min. The potential for atrial natriuretic peptide to shiftthe sensitivity of the exocytotic machinery to calcium was investigatedfurther in cells permeabilized with staphylococcal $alpha$ toxin. Thecalcium concentration was buffered by altering the ratio of EGTAto calcium, as described by Portzehl et al. (1964)

Digitonin (10 µM for 4 min) was used to permeabilize cells in six experiments involving C-type natriuretic peptide. Afterpermeabilization, cells were exposed to an intracellular bufferconsisting of potassium glutamate (137 mM), HEPES (10 mM), magnesiumchloride (5 mM), adenosine triphosphate (5 mM), EGTA (4 mM) andcalcium chloride (4 mM) containing either one of four concentrationsof C-type natriuretic peptide (0.01 to 10 nM) or its diluent (distilledwater). Catecholamines in the effluent and cells then were extractedand analyzed as described above.

Measurement of cytosolic free calcium concentration. The effect of natriuretic peptides on depolarization-induced alterations in intracellular calcium concentrations was determinedby monitoring fluorescence of the calcium sensitive dye, Fura-2(Grynkiewicz et al., 1985). Cells grown on coverslips were incubatedwith 1 µM Fura-2 acetoxymethyl ester in serum free Dulbecco'smodified Eagle's medium (pH 7.2) containing 0.05% bovine serumalbumin for 30 min at room temperature. Subsequently, the abovemedium was discarded and cells were incubated for an additional30 min in medium lacking Fura-2 acetoxymethyl ester to allow forthe deesterification of the intracellular dye. After incubation,cells were rinsed once with serum free media and twice with physiologicalsalt solution containing 118 mM NaCl, 5.0 mM KCl, 1.6 mM CaCl₂,1.2 mM MgCl₂, 1.2 mM Na₂HPO_4, 24 mM Hepes and 10 mM glucose (pH7.5). The coverslips were then set in Bellco chambers. After aninitial resting period in physiological salt solution, cells weretreated with 40 mM KCl in physiological salt solution to increaseintracellular calcium concentrations over basal levels. In identicalexperiments, cells were treated with 100 nM atrial natriureticpeptide in the depolarizing physiological salt solution to testfor its effects on intracellular calcium concentrations. Intracellularcalcium concentrations were determined by measuring the ratioof the Fura-2 fluorescence detected at 510 nm when excited ateither 340 or 380 nm (Grynkiewicz et al., 1985). Fluorescenceratios were converted to calcium concentrations, as describedby Grynkiewicz et al. (1985). The calibration values for R_maxand R_min were obtained by permeabilization of the cells with digitonin(10 µM) followed by the addition of EGTA (4 mM). The K_D valuewas taken as 135 nM since these experiments were performed atroom temperature (Grynkiewicz et al., 1985).

Fluorescence measurements with manganese quenching. Calcium conductance in PC12 cells was assessed using the manganese technique described by Merritt et al. (1989). Changes inintracellular manganese concentrations were measured by takingadvantage of the isobestic point of Fura-2, wavelength 357 nm,where the intensity of the fluorescence signal is independentof intracellular calcium concentrations. Cells were incubatedfor 5 min in a nominally calcium-free physiological salt solutioncontaining 500 µM manganese chloride before application of a nominallycalcium-free physiological salt solution containing 40 mM potassiumchloride. Either atrial natriuretic peptide (100 nM) or its vehiclewas included in the depolarizing calcium-free physiological saltsolution to assess its effect on manganese quenching. The excitationwavelength employed was 357 nm, while fluorescence was measuredat an emission wavelength of 510 nm.

Materials. Human atrial natriuretic peptide, $omega$ -conotoxin GVIA, nifedipine, caffeine, fetal calf serum, heat inactivated horse serum,7S-nerve growth factor, norepinephrine, dihydroxybenzylamine,dopamine, digitonin and A23187 were purchased from Sigma ChemicalCo. (St. Louis, MO). Staphylococcal $alpha$ toxin and Dulbecco's modifiedEagles medium were obtained from GIBCO BRL (Gaithersburg, MD).Rat tail collagen was purchased from Collaborative BiomedicalProducts (Bedford, MA). Fura-2 acetoxymethyl ester was obtainedfrom Molecular Probes, Inc. (Eugene, OR). C-type natriuretic peptidewas obtained from Peninsula Laboratories (Belmont, CA).

Statistical analysis. Concentration-response curves were compared by analysis of variance (ANOVA) for repeated measures and individual values werecompared by Student's paired t test with Dunnett's correctionfor multiple comparisons. P $<=$ .05 was considered statisticallysignificant.

	Results

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Involvement of specific calcium channels in neurotransmitter release. As shown in figure 1, dopamine efflux induced by the high potassium buffer averaged 12.4 ± 0.6% of total dopamine contentin the presence of vehicles for nifedipine, $omega$ -conotoxin, EGTAor ryanodine. Nifedipine (20 nM) and EGTA (2 mM) markedly inhibiteddopamine release to 7.1 ± 1.2% (P = .0004) and 2.6 ± 1.0% (P =.04), respectively. Neither $omega$ -conotoxin (500 nM) nor ryanodine(10 µM) significantly affected dopamine efflux, which averaged11.2 ± 1.3% (P = .14) and 13.1 ± 0.8% (P = .48), respectively,in their presence. These results are consistent with L-type calciumchannels being the major conduit for calcium inducing dopaminerelease in these cells; however, neither $omega$ -conotoxin-sensitivechannels nor intracellular ryanodine-sensitive calcium storesappear to participate in catecholamine release evoked by highpotassium concentrations in PC12 cells. The effectiveness of theryanodine concentration was confirmed by a 62 ± 2% attenuationof dopamine efflux evoked by 40 mM caffeine (P < .05; fig. 2).The concentrations of nifedipine and $omega$ -conotoxin have been demonstratedto be effective by prior investigators (Shafer and Atchison, 1991;Hirning et al., 1988). The pronounced reduction in catecholaminerelease in the presence of EGTA and nifedipine indicates thatextracellular calcium entering through L-type calcium channelsis the predominant stimulus for dopamine efflux initiated by depolarizationin these PC12 cells.

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Fig. 1. Dopamine release after exposure to high potassium (40 mM) buffer. Cells were incubated with one of the following agents inhigh potassium buffer for 5 min: 20 nM nifedipine, 500 nM $omega$ -conotoxin,2 mM EGTA, 10 µM ryanodine or their vehicles. Results with thevehicles were combined because no vehicle affected dopamine releaseevoked by the high potassium buffer. Numbers in parentheses indicatethe number of experiments per group. All values are means + S.E.The asterisk indicates a significant difference from culturesreceiving vehicles (*P < .05 by paired t test with Dunnett's correctionfor multiple comparisons).

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Fig. 2. Effect of ryanodine (10 µM) on dopamine efflux evoked by 40 mM caffeine. The asterisk indicates a significant effect of ryanodine(P < .05 by Student's paired t test). All values are means ± S.E.The number of experiments is indicated by the N.

Involvement of specific calcium channels in neuromodulatory effects of natriuretic peptides. Figure 3 illustrates the effects of atrial natriuretic peptide on dopamine release evoked by the high potassium buffer. Atrialnatriuretic peptide (100 nM) maximally suppressed dopamine efflux20 ± 3% of control release (P = .004). The effect of atrial natriureticpeptide was nearly maximal at concentrations as low as 1 nM, therefore,no EC₅₀ could be calculated. Attempts to better define the controlcurve were frustrated by the finding that a lower concentrationof atrial natriuretic peptide, 0.1 nM, failed to influence neurotransmitterefflux in six experiments.

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Fig. 3. Effect of atrial natriuretic peptide on dopamine release evoked by high potassium (40 mM) in the presence of nifedipine (20nM), ryanodine (10 µM) or their vehicle. Control release is takenas 100%. All values are means ± S.E. and are expressed as % ofcontrol. Atrial natriuretic peptide reduced dopamine efflux inthe presence of the vehicle or ryanodine but did not suppressdopamine release in the presence of nifedipine. The asterisksindicate a significant difference from cultures receiving thevehicle (P < .01 by ANOVA). The number of experiments performedin each group is indicated in parentheses.

The potential role of calcium channels in the neuromodulatory effect of atrial natriuretic peptide was assessed using inhibitorsof the various channels. The presence of nifedipine (20 nM) inthe high potassium buffer prevented atrial natriuretic peptidefrom reducing dopamine efflux (fig. 3). In fact, atrial natriureticpeptide tended to elevate dopamine efflux in the presence of nifedipine,although this effect was not statistically significant. Thus,treatment with nifedipine completely eliminated inhibitory neuromodulatoryeffects of atrial natriuretic peptide (P = .008 by ANOVA). Incontrast, neither $omega$ -conotoxin nor ryanodine altered the neuromodulatoryeffect of atrial natriuretic peptide (P = .60 and .80, respectively,data not shown for $omega$ -conotoxin because they obscure the controlcurve). These results are consistent with atrial natriuretic peptidereducing dopamine secretion either by modulating L-type calciumchannels or by affecting a process initiated by calcium enteringthrough L-type calcium channels.

Atrial natriuretic peptide effects on calcium homeostasis. Figure 4 depicts the effect of 100 nM atrial natriuretic peptide on intracellular calcium concentrations in the presence ofhigh potassium concentrations (40 mM) as a depolarizing stimulusover a time course of 2.9 min. The high potassium solution raisedthe level of intracellular calcium concentrations from a basalvalue of 75 ± 3 nM to 179 ± 13 nM. When the cells were challengedwith 100 nM atrial natriuretic peptide in the presence of thehigh potassium solution, intracellular calcium concentrationsincreased to 631 ± 197 nM. This effect was statistically significantcompared to the response observed in cells exposed to the highpotassium solution containing the atrial natriuretic peptide vehicle(P = .02). These surprisingly potentiative effects on intracellularcalcium concentrations were observed at atrial natriuretic peptideconcentrations as low as 0.1 nM (P = .02 by ANOVA, data not shown).Atrial natriuretic peptide failed to alter calcium concentrationswithin cells that were not depolarized (data not shown).

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Fig. 4. Effect of high potassium (KCl; 40 mM) in the presence of atrial natriuretic peptide (ANP 100 nM) or its diluent on cytosolicfree calcium concentrations. Atrial natriuretic peptide augmentedincreases in cytosolic free calcium concentrations (*P < .05 byANOVA) resulting from exposure to high potassium. All values aremeans ± S.E. obtained from 47 cells in three separate experiments.

Atrial natriuretic peptide could augment the effect of high potassium concentrations on intracellular calcium concentrationsby enhancing calcium conductance through the plasma membrane.This possibility was investigated by monitoring the intensityof Fura-2 fluorescence at 357 nm in the presence of extracellularmanganese. Figure 5 shows that addition of the calcium-free physiologicalsalt solution containing 40 mM potassium resulted in a time-dependentdecrease in fura-2 fluorescence. Atrial natriuretic peptide (100nM) in the presence of the depolarizing calcium-free physiologicalsalt solution accelerated the rate of Fura-2 quenching, as wasrevealed by a significantly greater slope in the cells treatedwith atrial natriuretic peptide (P = .0001). The time requiredto reduce fluorescence 50% averaged 42 ± 4 sec in the presenceof atrial natriuretic peptide and 72 ± 6 sec in the presence ofthe atrial natriuretic peptide diluent (P = .0001 by Student'st test). These data suggest that atrial natriuretic peptide increasesintracellular calcium levels by increasing a calcium conductancein the plasma membrane.

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Fig. 5. Effects of high potassium concentrations (KCl) on manganese entry in the presence of atrial natriuretic peptide (KCl + ANP(100 nM)) or its vehicle. The addition of atrial natriuretic peptidesignificantly accelerated the slope of the curve (***P < .0001).Values are expressed as means ± S.E. and the N indicates the numberof cells in which fluorescence was measured.

Atrial natriuretic peptide effects on exocytosis in response to calcium. The potentiative effect of atrial natriuretic peptide on intracellular calcium concentrations led us to examine whether atrialnatriuretic peptide lowered calcium sensitivity of the exocytoticprocess. We first measured the atrial natriuretic peptide effecton dopamine release in response to calcium influx induced by thecalcium ionophore A23187 (10 µM), which released 11.4 ± 2.0% ofthe total cellular dopamine content. Dopamine efflux in the presenceof A23187 was reduced by atrial natriuretic peptide to approximately40% of control (P < .05 relative to control release)(fig. 6).Staphylococcal $alpha$ toxin released 5.3 ± 0.2% of the total cellulardopamine content and atrial natriuretic peptide reduced dopamineefflux in a concentration-dependent manner, with a maximal inhibitionof approximately 60% occurring at a concentration of 10 nM (fig.6). Inasmuch as atrial natriuretic peptide reduced both A23187-and staphylococcal $alpha$ toxin-induced dopamine release, we concludethat atrial natriuretic peptide modulates a calcium sensitiveprocess to reduce dopamine efflux.

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Fig. 6. Effect of atrial natriuretic peptide on dopamine efflux resulting from calcium influx initiated by either the ionophore, A23187(10 µM), or cell permeabilization with staphylococcal $alpha$ toxin(Alpha toxin; 100 units/ml). Values are expressed as means ± S.E.and the number of experiments is indicated in parentheses. Asterisksindicate significant differences from the control value in theabsence of atrial natriuretic peptide (*P < .05, **P < .01 bypaired t test with Dunnett's correction for multiple comparisons).

An attempt was made to define further the interaction between calcium and atrial natriuretic peptide by testing if atrialnatriuretic peptide altered the potency of calcium in promotingdopamine efflux. As shown in figure 7, elevations in calcium concentrationsaugmented dopamine efflux to a maximum of 6.50 ± 0.58% of totaldopamine contents. Atrial natriuretic peptide (100 nM) suppressedthe efflux of dopamine in response to calcium without significantlyshifting the curve. The EC₅₀ values averaged 312 ± 120 and 308± 82 nM for the curves representing either vehicle or atrial natriureticpeptide treatment, respectively. Thus, the alteration in calciumsensitivity represents a generalized attenuation of the responseand not a displacement of the curve to the right.

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Fig. 7. The effect of atrial natriuretic peptide on the potency and efficacy of calcium in promoting dopamine efflux from cells permeabilizedwith staphylococcal $alpha$ toxin. All data points are means ± S.E.The number of experiments is indicated by the N. Atrial natriureticpeptide (ANP; 100 nM) significantly suppressed the response tocalcium (*P < .05 by ANOVA) without altering its potency.

C-type natriuretic peptide effects on exocytosis to calcium. The identity of the receptor mediating these actions of natriuretic peptides was investigated using C-type natriuretic peptide,a natriuretic peptide with selectivity for the natriuretic peptideC receptor in PC12 cells (Trachte et al., 1995). Evoked releasein the presence of A23187 (10 µM) or digitonin pretreatment wassimilar; therefore, the results were pooled and averaged 14.9± 2.4%. The C-type natriuretic peptide suppressed this evokedrelease to a maximum of 44 ± 13% at a concentration of 1 nM, asdepicted in Figure 8. The C-type natriuretic peptide acted similarlyto atrial natriuretic peptide, as presented in Figure 6. Furthermore,the C-type natriuretic peptide also tended to augment intracellularcalcium concentration increases in response to depolarization,although the elevations were neither as large as those in thepresence of atrial natriuretic peptide nor were they statisticallysignificant (data not shown). Finally, we ascertained that C-typenatriuretic peptide failed to influence cyclic guanosine monophosphateconcentrations at peptide concentrations altering dopamine efflux(data not shown). These last experiments are consistent with thenatriuretic peptide C receptor mediating the effects of natriureticpeptides to suppress catecholamine efflux.

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Fig. 8. The effect of C-type natriuretic peptide on dopamine efflux from cells permeabilized to calcium using either A23187 (10 µM)or digitonin (10 µM). All data points are means ± SE. The numberof experiments is indicated by the N. The asterisk indicates astatistically significant effect of C-type natriuretic peptideat a concentration of 1 nM (P < .05 by Student's t test with Dunnett'scorrection for multiple comparisons).

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

These results indicate that atrial natriuretic peptide suppresses catecholamine efflux in response to depolarizing stimuli(fig. 2) although augmenting both calcium conductance (fig. 5)in the cell membrane and calcium concentrations within the cell(fig. 4). Furthermore, natriuretic peptides suppressed calcium-dependentcatecholamine efflux (figs. 6, 7, 8). These data are consistentwith opposing effects of natriuretic peptides to increase intracellularcalcium concentrations while simultaneously desensitizing exocytoticprocesses to calcium. This pattern of activity is relatively uniquefor natriuretic peptides and somewhat similar to their effectsin the adrenal glomerulosa, in which natriuretic peptides bothaugment L-type calcium channel activity (McCarthy et al., 1990)and suppress aldosterone synthesis in response to calcium (Lotshawet al., 1991). Most investigators in other tissues find natriureticpeptides to suppress intracellular calcium concentrations andnone attribute natriuretic peptide actions to an altered sensitivityto calcium (Chiu et al., 1986; Hassid, 1986; Appel et al., 1987;Nascimento-Gomes et al., 1995). Therefore, this report supportsthe relatively novel concept that atrial natriuretic peptide modifiesthe sensitivity of cellular functions to calcium, in additionto its more widely recognized effects to alter intracellular calciumconcentrations.

This investigation also found that L-type calcium channels appear to account for nearly 50% of the calcium entry resultingin dopamine efflux in PC12 cells (fig. 1). Furthermore, atrialnatriuretic peptide was inactive as an inhibitory neuromodulatorin the presence of nifedipine (fig. 3). The persistence of atrialnatriuretic peptide neuromodulatory effects in the presence of $omega$ -conotoxin, and their abolition in the presence of nifedipine,suggests that atrial natriuretic peptide reduced catecholaminerelease by suppressing either calcium entry through L-type calciumchannels or a process affected by calcium influx through L-typecalcium channels. The natriuretic peptides are characteristicallynegative modulators of several biological functions. A classicalpathway invoked to explain this negative modulatory effect involvesa reduction of cytosolic calcium levels. The vasodilatory effectsof natriuretic peptides are partly mediated by decreased intracellularcalcium concentrations in vascular smooth muscle cells (Hassid,1986; Cornwell and Lincoln, 1988). Natriuretic peptides also reduceintracellular calcium concentrations in renal tissues (Appel etal., 1987; Nascimento-Gomes et al., 1995). An unexpected findingof this study is that atrial natriuretic peptide increased intracellularcalcium concentrations in depolarized cells (fig. 4) althoughreducing dopamine release (fig. 2). Atrial natriuretic peptidealso accelerated the quenching of fura-2 fluorescence in the presenceof extracellular manganese (fig. 5), suggesting that it elevatedintracellular calcium concentrations by augmenting calcium influxthrough channels in the plasma membrane. Atrial natriuretic peptideinhibits the low threshold T-type calcium channel but enhancescalcium current through the high threshold L-type channel in thebovine adrenal glomerulosa (McCarthy et al., 1990). Atrial natriureticpeptide not only reduces aldosterone release when the glomerulosacells are weakly depolarized, but also at strongly depolarizedpotentials when it enhances L-type channel activity (Barrett etal., 1991). A similar situation appears to exist in PC12 cells,wherein atrial natriuretic peptide reduces catecholamine releasewhile simultaneously increasing intracellular calcium concentrationsby enhancing extracellular calcium entry.

The mechanism accounting for the increased conductivity of calcium channels in the presence of atrial natriuretic peptidecould involve any of the calcium channels. Previous reports observednatriuretic peptides to increase calcium conductivity by L-typechannels in bovine adrenal glomerulosa (McCarthy et al., 1990;Barrett et al., 1991) and porcine renal cells (Dai and Quamme,1993). This mechanism could also be functioning in PC12 cells.Another report indicated that atrial natriuretic peptide increasedcalcium conductance by sodium channels in rodent cardiac tissue(Sorbera and Morad, 1990). This represents one of many possibilitiescapable of accounting for the large increase in calcium conductioncaused by atrial natriuretic peptide in our study.

The reduction of A23187- and staphyloccocal $alpha$ toxin-induced dopamine release by atrial natriuretic peptide suggests that atrialnatriuretic peptide affects a calcium-dependent process to suppressexocytosis (fig. 6). This result is in agreement with a previousstudy in which aldosterone secretion induced by A23187 was concentration-dependentlyinhibited by atrial natriuretic peptide in rat adrenal glomerulosacells (Lotshaw et al., 1991). In contrast to intact cells, whereatrial natriuretic peptide maximally reduces dopamine releaseby 20 to 40% (fig. 2), a 40 to 60% reduction in dopamine releasewas observed in permeabilized cells (fig. 6). The enhancementof a calcium conductance by atrial natriuretic peptide in intactcells may oppose the inhibitory neuromodulatory action of atrialnatriuretic peptide; however, the stabilized calcium concentrationspresent in permeabilized cells may allow the inhibitory neuromodulatoryeffect of atrial natriuretic peptide to proceed unopposed. Sucha scenario involving both potentiative and inhibitory effectsof atrial natriuretic peptide on neurotransmission could explainthe disparate magnitude of the inhibitory neuromodulatory effectof atrial natriuretic peptide in intact and permeabilized cells.

Atrial natriuretic peptide interacts with both the natriuretic peptide A and C receptors within PC12 cells (Drewett et al.,1988; Drewett et al., 1989b). Thus, the data obtained with atrialnatriuretic peptide failed to identify the receptor accountingfor its activity. Most natriuretic peptide responses are thoughtto be mediated by activation of guanylyl cyclases leading to elevationsin cyclic guanosine monophosphate concentrations (Anand-Srivastavaand Trachte, 1993). C-type natriuretic peptide interacts withboth the natriuretic peptide B and C receptor (Koller et al.,1991) but the PC12 cell line is devoid of the natriuretic peptideB receptor (Suga et al., 1992). Therefore, C-type natriureticpeptide represents a selective ligand for the natriuretic peptideC receptor in this cell line (Trachte et al., 1995). C-type natriureticpeptide exhibited the same neuromodulatory effect as atrial natriureticpeptide in permeablized cells (fig. 8). These data are consistentwith natriuretic peptide C receptors mediating natriuretic peptideeffects to attenuate catecholamine release from adrenergic tissueby attenuating catecholamine efflux in response to calcium.

In stark contrast to our findings indicating that natriuretic peptides suppress catecholamine efflux by activating the natriureticpeptide C receptor, Rodriguez-Pascual et al. (1996) found thatnatriuretic peptides suppress catecholamine efflux from bovinechromaffin cells by activating guanylyl cyclase and suppressingcalcium concentrations. The rationale for the different findingscould involve either the different cell types used or the differentexperimental conditions. For instance our results were obtainedafter five minute exposures to natriuretic peptides, whereas Rodriguez-Pascualet al. (1996) used 45-min experimental periods. Other investigatorsalso have observed stimulatory (Tsutsui et al., 1994) or inhibitoryeffects (Soares-da-Silva and Fernandes, 1992) of natriuretic peptideson catecholamine synthesis in bovine adrenal cells and rat kidney,respectively. Thus, the ultimate effects of natriuretic peptideson adrenergic tissue may be quite complex and involve multiplereceptors.

In conclusion, our results demonstrate that atrial natriuretic peptide reduces catecholamine release although simultaneouslyincreasing intracellular free calcium concentrations, probablyby facilitating calcium entry through the plasma membrane. Atrialnatriuretic peptide presumably affects an intracellular calcium-dependentprocess to suppress dopamine efflux, probably involving activationof the natriuretic peptide receptor C because C-type natriureticpeptide mimicked the action. The novel findings of this studyinclude the potentiative effects of atrial natriuretic peptideon calcium conductance and intracellular calcium concentrationsin adrenergic tissue, as well as the inhibition of calcium-induceddopamine exocytosis. The latter observation represents a relativelyunique finding, in that atrial natriuretic peptide previouslyhas been reported to alter the sensitivity of a biological processto calcium solely in the adrenal glomerulosa (Lotshaw et al.,1991).

	Acknowledgments

The authors thank Dr. J. Di Salvo and Dr. Lori Semenchuck for their assistance in the calcium imaging experiments and SueKurki for preparing the manuscript.

	Footnotes

Accepted for publication July 7, 1997.

Received for publication November 11, 1996.

¹ This work was supported by National Heart, Lung and Blood Grant RO1-HL-42525 and a Grant-in-aid from the University of MinnesotaGraduate School.

Send reprint requests to: Dr. George J. Trachte, Department of Pharmacology, School of Medicine, University of Minnesota-Duluth, Duluth, MN 55812.

	Abbreviations

ANP, atrial natriuretic peptide; PC12, pheochromocytoma cells; EGTA, ethyleneglycol-bis-( $beta$ -amino-ethyl ether)N, N $'$ -tetra-acetic acid; ANOVA, analysis of variance.

	References

Top Abstract Introduction Materials & Methods Results Discussion References

Anand-Srivastava, M. B. and Trachte, G. J.: Atrial natriuretic factor receptors and signal transduction mechanisms. Pharmacol. Rev. 45: 455-497, 1993.
Appel, R. G., Dubyak, G. R. and Dunn, M. J.: Effect of atrial natriuretic factor on cytosolic free calcium in rat glomerular mesangial cells. Febs. Lett. 224: 396-400, 1987.
Atlas, S. A. and Maack, T.: Effects of atrial natriuretic factor on the kidney and the renin-angiotensin-aldosterone system. Endocrinol. Metab. Clin. North Am. 16: 107-143, 1987.
Babinski, K., Haddad, P., Vallerand, D., McNicoll, N., De Léan, A. and Ong, H.: Natriuretic peptides inhibit nicotine-induced whole-cell currents and catecholamine secretion in bovine chromaffin cells: evidence for the involvement of the atrial natriuretic factor R₂ receptors. J. Neurochem. 64: 1080-1087, 1995.
Barrett, P. Q., Isales, C. M., Bollag, W. B. and McCarthy, R. T.: Ca²⁺ channels and aldosterone secretion: modulation by K⁺ and atrial natriuretic peptide. Am. J. Physiol. 261: F706-F719, 1991.
Chiu, P. J. S., Tetzloff, G. and Sybertz, E. J.: The effects of atriopeptin II on calcium fluxes in rabbit aorta. Eur. J. Pharmacol. 124: 277-284, 1986.
Cornwell, T. L. and Lincoln, T. M.: Regulation of phosphorylase A formation and calcium content in aortic smooth muscle and smooth muscle cells: effects of atrial natriuretic peptide II. J. Pharmacol. Exp. Ther. 247: 524-530, 1988.
Dai, L.-J. and Quamme, G. A.: Atrial natriuretic peptide initiates Ca²⁺ transients in isolated renal cortical thick ascending limb cells. Am. J. Physiol. 265: F592-F597, 1993.
Debinski, W., Kuchel, O. and Buu, N. T.: Atrial natriuretic factor is a new neuromodulatory peptide. Neuroscience 36: 15-20, 1990.
de Bold, A. J., Borenstein, H. B., Veress, A. T. and Sonnenberg, H.: A rapid and potent natriuretic response to intravenous injection of atrial myocardial extract in rats. Life Sci. 28: 89-94, 1981.
Drewett, J., Marchand, G., Ziegler, R. and Trachte, G.: Atrial natriuretic factor inhibits norepinephrine release in an adrenergic clonal cell line (PC12). Eur. J. Pharmacol. 150: 175-179, 1988.
Drewett, J. G., Trachte, G. J. and Marchand, G. R.: Atrial natriuretic factor inhibits adrenergic and purinergic neurotransmission in the rabbit isolated vas deferens. J. Pharmacol. Exp. Ther. 248: 135-142, 1989a.
Drewett, J. G., Ziegler, R. J., Marchand, G. R. and Trachte, G. J.: Cyclic guanosine 3 $'$ ,5 $'$ monophosphate mediates the inhibitory effect of atrial natriuretic factor in adrenergic, neuronal pheochromocytoma cells. J. Pharmacol. Exp. Ther. 250: 428-432, 1989b.
Furukawa, K.-I., Tawada, Y. and Shigekawa, M.: Regulation of the plasma membrane Ca²⁺ pump by cyclic nucleotides in cultured vascular smooth muscle cells. J. Biol. Chem. 263: 8058-8065, 1988.
Giridhar, J., Peoples, R. W. and Isom, G. E.: Modulation of hypothalamic norepinephrine release by atrial natriuretic peptide: involvement of cyclic GMP. Eur. J. Pharmacol. 213: 317-321, 1992.
Gisbert, M.-P. and Fischmeister, R.: Atrial natriuretic factor regulates the calcium current in frog isolated cardiac cells. Circ. Res. 62: 660-667, 1988.
Grynkiewicz, G., Poenie, M. and Tsien, R. Y.: A new generation of calcium indicators with greatly improved fluorescence properties. J. Biol. Chem. 260: 3440-3450, 1985.
Hassid, A.: Atriopeptin II decreases cytosolic free Ca in cultured vascular smooth muscle cells. Am. J. Physiol. 251: C681-C686, 1986.
Hirning, L. D., Fox, A. P., McCleskey, E. W., Olivera, B. M., Thayer, S. A., Miller, R. J. and Tsien, R. W.: Dominant role of N-type Ca²⁺ channels in evoked release of norepinephrine form sympathetic neurons. Science 239: 57-61, 1988.
Isales, C. M., Lewicki, J. A., Nee, J. J. and Barrett, P. Q.: ANP-(7-23) stimulates a DHP-sensitive Ca²⁺ conductance and reduces cellular cAMP via a cGMP-independent mechanism. Amer. J. Physiol. 263: C334-C342, 1992.
Kelly, R. B., Deutsch, J. W., Carlson, S. S. and Wagner, J. A.: Biochemistry of neurotransmitter release. Ann. Rev. Neurosci. 2: 399-446, 1979.
Koller, K. J., Lowe, D. G., Bennett, G. L., Minamino, N., Kangawa, K., Matsuo, H. and Goeddel, D. V.: Selective activation of the B natriuretic peptide receptor by C-type natriuretic peptide (CNP). Science 252: 120-123, 1991.
Le Grand, B., Deroubaix, E., Couetil, J.-P. and Coraboeuf, E.: Effects of atrionatriuretic factor on Ca²⁺ current and Ca_i-independent transient outward K⁺ current in human atrial cells. Pflugers Arch. 421: 486-491, 1992.
Lotshaw, D. P., Franco-Saenz, R. and Mulrow, P. J.: Atrial natriuretic peptide inhibition of calcium ionophore A23187-stimulated aldosterone secretion in rat adrenal glomerulosa cells. Endocrinology 129: 2305-2310, 1991.
McCarthy, R. T., Isales, C. M., Bollag, W. B., Rasmussen, H. and Barrett, P. Q.: Atrial natriuretic peptide differentially modulates T- and L- type calcium channels. Am. J. Physiol. 258: F473-F478, 1990.
Merritt, J. E., Jacob, R. and Hallam, T. J.: Use of manganese to discriminate between calcium influx and mobilization from internal stores in stimulated human neutrophils. J. Biol. Chem. 264: 1522-1527, 1989.
Nakamaru, M. and Inagami, T.: Atrial natriuretic factor inhibits norepinephrine release evoked by sympathetic nerve stimulation in isolated perfused rat mesenteric arteries. Eur. J. Pharmacol. 123: 459-461, 1986.
Nascimento-Gomes, G., Souza, M. O., Vecchia, M. G., Ferreira, A. T. and Mello-Aires, M.: Atrial natriuretic peptide modulates the effect of angiotensin II on the concentration of free calcium in the cytosol of Mandin-Darby canine kidney cells. Braz. J. med. Biol. Res. 28: 609-613, 1995.
Oda, S., Sano, T., Morishita, Y. and Matsuda, Y.: Pharmacological profile of HS-142-1, a novel nonpeptide atrial natriuretic peptide (ANP) antagonist of microbial origin. II. Restoration by HS-142-1 of ANP-induced inhibition of aldosterone production in adrenal glomerulosa cells. J. Pharmacol. Exp. Ther. 263: 241-245, 1992.
Pella, R.: The protective effect of atrial natriuretic peptide (ANP) on cells damaged by oxygen radicals is mediated through elevated cGMP levels, reduction of calcium inflow and probably G proteins. Biochem. Biophys. Res. Commun. 174: 549-555, 1991.
Portzehl, H., Caldwell, P. C. and Ruegg, J. C.: The dependence of contraction and relaxation of muscle fibres from the crab maia Squinado on the internal concentration of free calcium ions. Biochem. Biophys. Acta 79: 581-591, 1964.
Rodriguez-Pascual, F., Miras-Portugal, M. T. and Torres, M.: Effect of cyclic GMP-increasing agents nitric oxide and C-type natriuretic peptide on bovine chromaffin cell function: Inhibitory role mediated by cyclic GMP-dependent protein kinase. Mol. Pharmacol. 49: 1058-1070, 1996.
Shafer, T. J. and Atchison, W. D.: Methylmercury blocks N- and L-type Ca⁺⁺ channels in nerve growth factor-differentiated pheochromocytoma (PC12) cells. J. Pharmacol. Exp. Ther. 258: 149-157, 1991.
Sorbera, L. A. and Morad, M.: Atrionatriuretic peptide transforms cardiac sodium channels into calcium-conducting channels. Science 247: 969-973, 1990.
Soares-da-Silva, P. and Fernandes, M. H.: Effect of a-human atrial natriruetic peptide on the synthesis of dopamine in the rat kidney. Br. J. Pharmacol. 105: 869-874, 1992.
Suga, S. K., Nakao, K., Hosoda, K., Mukoyama, M., Ogawa, Y., Shirakami, G., Arai, H., Saito, Y., Kambayashi, Y., Inouye, K. and Imura, H.: Receptor selectivity of natriuretic peptide family atrial natriuretic peptide, brain natriuretic peptide and C-type natriuretic peptide. Endocrinology 130: 229-239, 1992.
Trachte, G. J., Kanwal, S., Elmquist, B. J. and Ziegler, R. J.: C-type natriuretic peptide neuromodulates via clearance receptors. Am. J. Physiol. 268: C978-C984, 1995.
Tsutsui, M., Yanagihara, N., Minami, K., Kobayashi, H., Nakashima, Y., Kuroiwa, A. and Izumi, F.: C-type natriuretic peptide stimulates catecholamine synthesis through the accumulation of cyclic GMP in cultured bovine adrenal medullary cells. J. Pharmacol. Exp. Ther. 268: 584-589, 1994.
White, R. E., Lee, A. B., Shcherbatko, A. D., Lincoln, T. M., Schonbrunn, A. and Armstrong, D. L.: Potassium channel stimulation by natriuretic peptides through cGMP-dependent dephosphorylation. Nature 361: 263-266, 1993.

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Atrial Natriuretic Peptide Inhibits Evoked Catecholamine Release by Altering Sensitivity to Calcium1

Atrial Natriuretic Peptide Inhibits Evoked Catecholamine Release by Altering Sensitivity to Calcium¹