Low-Threshold Exocytosis Induced by cAMP-Recruited CaV3.2 ({alpha}1H) Channels in Rat Chromaffin Cells

doi:10.1529/biophysj.105.071647

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Low-Threshold Exocytosis Induced by cAMP-Recruited Ca_V3.2 ( ${alpha}$ _1H) Channels in Rat Chromaffin Cells

A. Giancippoli, M. Novara, A. de Luca, P. Baldelli, A. Marcantoni, E. Carbone and V. Carabelli

Department of Neuroscience, NIS Centre of Excellence, CNISM Research Unit, 10125 Turin, Italy

Correspondence: Address reprint requests to Emilio Carbone, Dept. of Neuroscience, Corso Raffaello 30, 10125 Turin, Italy. Tel.: 39-011-670-7786; Fax: 39-011-670-7708; E-mail: emilio.carbone{at}unito.it.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

We have studied the functional role of Ca_V3 channels in triggeringfast exocytosis in rat chromaffin cells (RCCs). Ca_V3 T-typechannels were selectively recruited by chronic exposures tocAMP (3 days) via an exchange protein directly activated bycAMP (Epac)-mediated pathway. Here we show that cAMP-treatedcells had increased secretory responses, which could be evokedeven at very low depolarizations (–50, –40 mV).Potentiation of exocytosis in cAMP-treated cells did not occurin the presence of 50 µM Ni²⁺, which selectively blocksT-type currents in RCCs. This suggests that the "low-thresholdexocytosis" induced by cAMP is due to increased Ca²⁺ influxthrough cAMP-recruited T-type channels, rather than to an enhancedsecretion downstream of Ca²⁺ entry, as previously reported forshort-term cAMP treatments (20 min). Newly recruited T-typechannels increase the fast secretory response at low voltageswithout altering the size of the immediately releasable pool.They also preserve the Ca²⁺ dependence of exocytosis, the initialspeed of vesicle depletion, and the mean quantal size of singlesecretory events. All this indicates that cAMP-recruited Ca_V3channels enhance the secretory activity of RCCs at low voltagesby coupling to the secretory apparatus with a Ca²⁺ efficacysimilar to that of already existing high-threshold Ca²⁺ channels.Finally, using RT-PCRs we found that the fast inactivating low-thresholdCa²⁺ current component recruited by cAMP is selectively associatedto the ${alpha}$ _1H (Ca_V3.2) channel isoform.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Regulated exocytosis in chromaffin cells is mainly controlledby Ca_V1 and Ca_V2 voltage-gated Ca²⁺ channels even though theirexpression varies among animal species and their coupling tosecretion remains controversial (1–9). Several reportsindicate that exocytosis is preferentially controlled by Ca_V1(L-type), Ca_V2.1 (P/Q-type), or Ca_V2.3 (R-types) (8,10–12),suggesting specific colocalization of Ca²⁺ channels to secretorysites. Alternatively, other works favor the idea that Ca²⁺ channelscontribute equally to exocytosis, depending on their densityand contribution to the overall Ca²⁺ current (13–18).In particular, release depends on the total Ca²⁺ charge enteringthe cell and on the filling state of the readily releasablepool (RRP) (19,20). There is also evidence that whereas in sphericalchromaffin cells secretion is randomly distributed, in neurite-emittingchromaffin cells, vesicles and clusters of P/Q-type channelsare colocalized at the release sites of neurite terminals andL-type channels are uniformly distributed (21).

Besides these controversies, very little is known about theexpression of functional T-type channels and their couplingto secretion in chromaffin cells. T-type channels are expressedin bovine chromaffin cells (BCCs) (22), in immature rat chromaffincells (RCCs) (23), and in a small percentage of adult RCCs (24).Recently, we have shown that in most RCCs, 3–5 days exposureto pCPT-cAMP induces the expression of Ca_V3 channels withoutaltering the proportions of other Ca²⁺ channels (25). This long-termaction of cAMP clearly has different consequences with respectto the short-term effects (1 mM, 30 min), which cause upregulationof L-type channel gating and marked increase of secretion downstreamof the Ca²⁺ entry (14,26,27). Thus, prolonged exposures to pCPT-cAMPappear useful for studying whether newly synthesized T-typechannels are effectively coupled to catecholamine secretionin RCCs.

To date there are few reports suggesting a role of T-type channelsin neurosecretion. T-type channels sustain the secretion ofaldosterone in the adrenal glomerulosa (28), control insulinrelease in INS-1 ß-cells (29) and the release of atrialnatriuretic factor in rat cardiomyocytes (30), and mediate fastexocytosis in melanotropes (31), retinal bipolar cells (32),and mouse pheochromocytoma cell lines (MPC 9/3L) (33). In immatureRCCs, T-type channels contribute markedly to the total Ca²⁺current but fail to produce secretion (23). This suggests thateither their activation-secretion coupling requires some criticalelement that is missing during development or, alternatively,they are located apart from release sites contradicting theobservation that secretion in adult RCCs occurs regardless ofthe type of functioning Ca²⁺ channels (14). To solve these issues,we raised the question whether cAMP-recruited T-type channelsare involved in depolarization-evoked exocytosis and how theyare possibly coupled to the exocytic machinery in adult RCCs.

Here, we show that long-term exposures to cAMP uniquely recruitthe Ca_V3.2 ( ${alpha}$ _1H) channel isoform uncovering a "low-threshold"secretory response that is normally absent in control RCCs.The cAMP-enhanced secretion exhibits the typical sensitivityto Ni²⁺ of Ca_V3.2 T-type channels and is absent when eitherL or R are the only Ca²⁺ channels available. This suggests strictcorrelation to the Ca²⁺ influx through T-type channels, ratherthan an effect on the secretory machinery downstream of Ca²⁺entry. The "low-threshold" potentiation of exocytosis by cAMPtreatment was mainly associated with an increased Ca²⁺ chargerecruited at negative potentials and preserved the size of theimmediately releasable pool (IRP) mobilized by short depolarizations,the Ca²⁺ dependence of exocytosis and the quantal size of singlesecretory events. Thus, cAMP-recruited Ca_V3.2 channels appeareffectively coupled to the secretory apparatus and control fastexocytosis in a way comparable to Ca_V1 and Ca_V2 channels.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Isolation and culture of rat chromaffin cells
Chromaffin cells were obtained from the adrenal glands of adultSprague Dawley rats (200–300 g) as previously described(14). All experiments were carried out in accordance with theguidelines established by the National Council on Animal Careand were approved by the local Animal Care Committee of TurinUniversity. Before cell plating, plastic dishes were pretreatedwith poli-L-ornithine (1 mg/ml) and laminin (5 µg/ml inL-15 carbonate) for improving cell adhesion. Cells were thencultured at 37°C in a water-saturated atmosphere with 5%CO₂. Culture medium contained Dulbecco's modified Eagle's medium,penicillin-streptomycin 0.5%, and gentamycin 0.25%, was serum-free,and was not changed during the culture period. After 24 h sincetheir plating, cells were exposed to the membrane permeablecAMP analog pCPT-cAMP (200 µM) and then maintained upto 5 days (4 days with cAMP) in the culture medium (25).

RNA extraction and reverse transcription-polymerase chain reaction
Total RNA was isolated from both control and 3 days cAMP-treatedchromaffin cells with the RNeasy Micro Kit (Qiagen; AG, Basel,Switzerland) as indicated in the manufacturer's instructions.The cDNA was synthesized from 0.5 µg of DNase-treatedtotal RNA in a total volume of 20 µl with the SuperScriptFirst-Strand Synthesis System for RT-PCR (Life Technologies;Carlsbad, CA). RT-PCR experiments were carried out in a totalvolume of 25 µl, containing 10 µl of cDNA, 0.5 unitsof high-fidelity DNA polymerase, 5X Phusion GC buffer, 0.2%DMSO (Finnzymes, Espoo, Finland), and 0.2 mM of each deoxynucleotidetriphosphate (Life Technologies) and 0.5 µM specific primerset. The primer sequences used were for ${alpha}$ ₁H (AF290213): 5'-GACGAGGATAAGACGTCT-3'and 5'-AGGAGACGCGTAGCCTGTT-3'; for ${alpha}$ ₁G (AF290212): 5'-TCAGAGCCTGATTTCTTT-3'and 5'-CAGGAGACGAAACCTTGA-3'; for ${alpha}$ 1I (AF290214): 5'-GATGAGGACCAGAGCTCA-3' and 5'-CAGGATCCGGAACTTGTT-3'; for ß-actin(NM_031144) 5'-GGACCTGACAGACTACCTCA-3' and 5'-ATCTTGATCTTCATGGTGCT-3';for dopamine ß-hydroxilase (DBH; NM_013158) 5'-CCTTGAAGGGACTTTAGAGC-3'and 5'-AGCAGCTGGTAGTCCTGATG-3'. The cycling conditions were98°C for 30 s, followed by 26 cycles of 98°C for 15s, either 58°C (for ${alpha}$ ₁H, ß-actin, and DBH) or 64°C( ${alpha}$ ₁G and ${alpha}$ ₁I) for 30 s and 72°C for 30 s. Positive (cDNA obtainedfrom rat cerebellum total RNA) and negative (water instead oftemplate) controls were amplified in the same conditions. ThePCR product was run on 1.2% agarose gel stained with Gel Star(Cambrex; East Rutherford, NJ) in the presence of a 100 bp DNAladder as the molecular weight marker (Promega; Madison, WI).The intensity of ${alpha}$ 1H, DBH, and ß-actin bands was measuredusing dedicated software (ImageJ 1.33u). To minimize intrinsicvariation, results were normalized to the amount of ß-actinexpression. All samples were tested simultaneously for the differentprimer sets.

Electrophysiological recordings
Ca²⁺ currents and capacitance increases were measured in theperforated-patch configuration by means of an EPC-9 patch-clampamplifier (Heka-Electronic; Lambrecht, Germany) and PULSE software.Patch-clamp pipettes were fabricated from thin Kimax borosilicateglass (Witz Scientific; Holland, OH) and fire-polished to obtaina final series resistance of 2–3 M ${Omega}$ .

Recordings started when the access resistance was below 15 M ${Omega}$ , $~$ 10 min after sealing (34). Ca²⁺ currents were sampled at 10kHz and filtered at 2 kHz. The holding potential (Vh) was keptat –80 mV, and test depolarizations (10–200 ms)varied from –50 to +40 mV, except when otherwise indicated.The quantity of charge Q was evaluated as the time integralof the inward Ca²⁺ current. Exocytosis was estimated by meansof capacitance increments ( ${Delta}$ C) by applying sinusoidal wave functions(±25 mV, 1 KHz) as previously described (14). Capacitanceincrements due to activation of voltage-gated Ca²⁺ channelswere acquired at high time resolution using "PULSE" software,whereas at time intervals between step depolarizations, capacitancedata were recorded at low time resolution using the X-Chartplug-in module of "PULSE". To determine the ${Delta}$ C increment, membranecapacitance was averaged over 50 ms preceding the depolarizationto give a reference value; this was subtracted from the valueestimated after the depolarization, averaged over a 400 ms window,excluding the first 50 ms to avoid contamination by nonsecretorycapacitative transients. Experiments were carried out at roomtemperature (22–24°C). Data are given as mean ±SE for n = number of cells. Statistical significance was calculatedusing unpaired Student's t-test, and p values <0.05 wereconsidered significant. Fast capacitative transients duringstep depolarization were minimized online by the patch-clampanalog compensation. Currents were not corrected for leakage,and for this reason cells with leakage currents >15 pA atVh were excluded from the analysis.

Solutions
The extracellular solution contained (mM) 145 TEACl, 5 CaCl₂,10 glucose, 10 HEPES (pH 7.4 with CsOH). Except where otherwisespecified, cells were incubated 15 min before recordings with ${omega}$ -conotoxin-GVIA (3.2 µM) and ${omega}$ -agatoxin-IVA (2 µM)(Scientific Marketing Associates; Barnet, UK) into an extracellularsolution containing 2 mM instead of 5 mM CaCl₂.

Amphotericin B (Sigma, St. Louis, MO) was used to achieve theperforated patch configuration (14). Amphotericin B was dissolvedin dimethyl sulfoxide (DMSO) and stocked at –20°Cin aliquots of 50 mg/ml. The pipette-filling solution contained(mM): 135 CsMeSO₃, 8 NaCl, 2 MgCl₂, 20 HEPES, and 50–100µg/ml amphotericin B (pH 7.3 with CsOH).

Series resistance was compensated by 80% and monitored duringthe experiment. Since the drugs applied to the external solutiondid not affect the liquid junction potential (LJP), the indicatedvoltages were not corrected for the LJP at the interface betweenthe pipette solution (135 mM CsMeSO₃) and the bath (5 mM Ca²⁺and 145 mM TEACl), which was 24.5 mV (35). Compared to previousmeasurements in whole-cell clamp recordings in 10 mM Ca²⁺ and137 mM TRIS-HCl (LJP = 13.6 mV) (25), the voltage bias was $~$ 10mV more positive. However, since 5 mM Ca²⁺ induces an $~$ 8 mV negativeshift of voltage-dependent parameters with respect to 10 mMCa²⁺, these recordings are comparable to those previously reportedby Novara et al. (25).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Long-term exposures to pCPT-cAMP selectively potentiate the expression of the ${alpha}$ _1H mRNA subunit in RCCs
We have recently shown that 3–5 days exposure to the membranepermeable cAMP analog pCPT-cAMP (200 µM) induces the recruitmentof T-type channels in RCCs, which are not usually expressedin these cells (25). The fast inactivation kinetics ( ${tau}$ _inact 18–20ms at +10 mV) and the high sensitivity to Ni²⁺ block (IC₅₀ 16µM in 10 mM Ca²⁺) suggested that the cAMP-recruited T-typecurrents were most likely associated with the Ca_V3.2 channelisoform (36,37). To verify this, we ran a series of RT-PCRsaimed at identifying the molecular isoform involved.

RT-PCRs with primers against ${alpha}$ _1G, ${alpha}$ _1H, and ${alpha}$ _1I subunits of Ca_v3T-type channels were performed on total RNA from RCCs. We comparedthe subunit's expression level between control and 3 days cAMP-treatedcells by applying nonsaturating PCR conditions. In addition,we used primers for DBH and for the housekeeping gene ß-actinto evaluate RNA integrity (Fig. 1, A–C). DBH was usedsince it is specifically expressed by chromaffin cells and upregulatedby cAMP (38). RT-PCRs with primers against ${alpha}$ _1G and ${alpha}$ _1I revealedno messengers in control and cAMP-treated cells, whereas positivecontrols gave the expected products (Fig. 1, B and C). In contrast,in cAMP-treated cells we found marked expression of both the ${alpha}$ _1H subunit and DBH mRNA, even though a smaller constitutiveexpression of the subunit was also found in cAMP-untreated cells(Fig. 1 A). This agrees with the observations that a small percentageof control cells (<10%) exhibited sizeable low-thresholdcurrents. In addition, semiquantitative RT-PCR analysis indicateda 3.5-fold increase of ${alpha}$ _1H expression after cAMP treatment (seeMaterials and Methods). Taken together, our results suggestthat long-term incubations with cAMP selectively enhance thelevel of ${alpha}$ _1H mRNA.

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FIGURE 1 Differential expression of ${alpha}$ _1H calcium channel subunit mRNA in control and cAMP-treated RCCs. Total RNA (0.5 µg) from adult RCCs was retrotranscribed and amplified with specific oligonucleotides (0.5 µM) for ${alpha}$ _1H, ${alpha}$ _1G, ${alpha}$ _1I, DBH, and ß-actin. (A) Upregulation of ${alpha}$ _1H T-type channel after long-term cAMP treatment. PCR products for ${alpha}$ _1H (lanes 1 and 4), for DBH (lanes 2 and 5) and ${alpha}$ _1H plus ß-actin (lanes 3 and 6). Control cells are in lanes 1–3 and cAMP-treated cells in lanes 4–6. mRNA from the entire rat brain is used as positive control (lane 7). cDNA replaced with water is used as a negative control (lane 8). (B and C) The ${alpha}$ _1G and ${alpha}$ _1I subunits are not expressed in control and in cAMP-treated RCCs. The PCR products for ${alpha}$ _1G and ${alpha}$ _1I (lanes 1 and 3), ${alpha}$ _1G plus ß-actin, and ${alpha}$ _1I plus ß-actin (lanes 2 and 4) are shown in control (lanes 1 and 2) and cAMP-treated cells (lanes 3 and 4). Positive and negative controls for the reaction are the mRNA from entire rat brain (lane 5) and replacement of cDNA with water (lane 6). PCR products were separated in 1.2% agarose gel in the presence of 100 bp DNA ladder (lane MW).

Exocytosis associated with T-type channels in cAMP-treated RCCs
To focus on the secretory responses evoked by T-type currents,N-, P/Q-, and L-type channels were blocked by pretreating theRCCs with mixtures of ${omega}$ -CTx-GVIA (3.2 µM) and ${omega}$ -Aga-IVA(2 µM) for 15 min before the experiment and by adding1 µM nifedipine to the external solution. Attempts toblock the R-type channels using the selective blocker SNX-482(39

) failed due to the insensitivity of Ca²⁺ currents to highconcentrations of the toxin (0.1–1 µM) (25

). Thus,our recordings mainly contained R-type currents in control conditionsand mixtures of T- and R-type currents in cAMP-treated cells.In control RCCs the R-type current started activating above–30 mV, had fast activation, relatively slow inactivationkinetics (Figs. 2 A and 3 A), and in most cells (90%, n = 25)the current-voltage (I/V) relationship had a single negativepeak around +10 mV (Fig. 2 B). In the remaining 10% of cells,T-type currents could also be detected at very negative potentials.These RCCs, however, were not included in the statistics ofcontrol cells. In cAMP-treated cells, Ca²⁺ currents startedactivating at more negative potentials (–40 mV), had fastactivation and rapid inactivation, and showed I/V curves witha second "peak" at $~$ –20 mV (87%, n = 79), confirming thatin cAMP-treated RCCs T-type currents coexisted with R-type currents(Figs. 2 A and 3 A).

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FIGURE 2 Low-threshold Ca²⁺ current upregulation by long-term cAMP treatment. (A) Comparison of representative Ca²⁺ currents in control cells and after long-term exposure to pCPT-cAMP ( ${circ}$ ). Depolarizations at –40, –30, and +10 mV from –80 mV holding potential. Cells were previously incubated with ${omega}$ -CTx-GVIa (3.2 µM) and ${omega}$ -Aga-IVa (2 µM); nifedipine (1 µM) was kept in the external solution. After cAMP treatment, Ca²⁺ currents are already detectable at –40 mV and become more rapidly inactivating at higher potentials. (B) The low-threshold component is more evident when applying a ramp command (from –80 mV to +60 mV), which produces an early peak at $~$ –15 mV.

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FIGURE 3 Long-term cAMP treatment potentiates the quantity of charge and secretion at low voltages. (A) Ca²⁺ currents and depolarization-evoked secretory responses for a control cell (left) and after long-term incubation with pCPT-cAMP (right). Cells were incubated with ${omega}$ -toxins and nifedipine was in the bath. (B) Quantity of charge is calculated as the time integral of the current entering during the 100 ms depolarization; data are averaged from 25 cAMP-untreated ( ${blacksquare}$ ) and 69 cAMP-treated cells ( ${circ}$ ), respectively. Experimental data were fitted to polynomial functions. (C) The corresponding secretion was measured by means of ${Delta}$ C increases at the potentials indicated and plotted versus voltage.

Having shown that cAMP selectively recruits ${alpha}$ _1H T-type channelsubunits, we next measured their associated exocytosis. Stepdepolarizations lasting 100 ms were applied from –50 mVto +40 mV. With respect to previous studies (14

), we reducedthe extracellular [Ca²⁺] (from 10 to 5 mM) and replaced Na⁺with TEA⁺ to minimize Na⁺ inward currents. Replacement of Na⁺with TEA⁺ was preferred to the addition of tetrodotoxin dueto the slowing-down of Na⁺ gating currents by the toxin (40

).On the other hand, block of transient inward Na⁺ currents wascrucial for the correct estimate of the total Ca²⁺ charge associatedwith cAMP-recruited T-type channels. External solutions containingTEA⁺ did not significantly alter the T-type current densityand secretion. In fact 1), the density of T-type currents (25

)and the secretion associated with various Ca²⁺ channels werecomparable to those reported in Na⁺ containing solutions. In10 mM Ca²⁺ and 135 mM Na⁺, a charge density of 1.7 pC/pF carriedby L- and R-type channels produces a mean ${Delta}$ C of 24 fF at +10mV (14

), which compares well with the 15 fF capacity changeinduced by 1.0 pC/pF through the same channels in 5 mM Ca²⁺and 145 mM TEA⁺ (see Fig. 6 A). 2), During the experiments,the RCCs were clamped to –80 mV, and in the short periodpreceding the clamping conditions (4–6 min) the secretionafter TEA-induced depolarization was transient and lasted only2–3 min, most likely because of Ca²⁺ channel inactivation(data not shown). We tested this by measuring the amperometricspikes associated to catecholamine secretion with carbon fibermicroelectrodes.

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FIGURE 6 Long-term cAMP treatment does not alter L-type channel functionality and the related secretion. In sharp contrast to the action exerted on T-type channels, the long-term treatment with pCPT-cAMP failed to alter the functionality of nifedipine-sensitive L-type channels. (A) The charge entering during 120 ms depolarization at +10 mV and the depolarization-evoked secretion are not modified by cell incubation with pCPT-cAMP. (B) Representative traces of L-type currents and corresponding ${Delta}$ C increases without and after cAMP treatment. To further inactivate N- and P/Q-type channels, a conditioning prepulse to –40 mV preceded the test depolarization (14

As shown in Fig. 3, in control RCCs secretion started around–30 mV and reached maximal values at +10 mV ( $~$ 17 fF n =25, Fig. 3, B and C), in good agreement with the voltage dependenceof Ca²⁺ charge, which started contributing around –30mV and peaked at +10 mV. In most cAMP-treated RCCs' (87% of79 cells) secretory responses could already be detected at verynegative depolarization (–50, –40 mV). Exocytosisand quantity of charge were more prominent between –50mV (p < 0.01) and –20 mV (p < 0.05), where T-typechannels were activated and R-types contributed less (Fig. 3 C).Quantity of charge and capacitance increases reached maximalvalues at 0 mV (21 fF). Interestingly, the presence of T-typecurrents produced a broadening of both Q(V) and ${Delta}$ C(V) curvestoward negative voltages rather than a second "peak" on theI/V characteristics (Fig. 2). This derives most likely fromthe peculiar voltage dependence of T-type channel gating, whichproduces sharp increases of the peak current between –40and +10 mV followed by an increased rate of inactivation. Theincreased inactivation limits the quantity of Ca²⁺ charge flowingduring pulses of 100 ms and produces weak voltage dependenceof the Q(V) curve associated with T-type channels. This is particularlyevident between –30 and 0 mV, where the quantity of chargeattributed to T-type channels is nearly unchanged, as can beinferred from the flat Q versus V relationship in cAMP-treatedcells from –30 to 0 mV (Fig. 3, B and C). A similar weakvoltage dependence is evident in the ${Delta}$ C(V) curve.

Ni²⁺ blocks the low voltage-activated exocytosis associated with T-type current recruitment
Ni²⁺ is a potent blocker of Ca_V3.2 ( ${alpha}$ _1H) T-type channels (37)and is commonly used to separate T-types from residual high-voltageactivated (HVA) currents, even though some R-type channel displayslower sensitivity to Ni²⁺ block (41). Fig. 4 A shows representativeexamples of the action of 50 µM Ni²⁺ (at –20 mV)on Ca²⁺ currents and exocytosis in cAMP-untreated and cAMP-treatedcells. It is evident that Ni²⁺ exerted negligible effects inuntreated cells, whereas it reduced the secretion by $~$ 45% andabolished the fast inactivating currents in cAMP-treated RCCs.The most significant reduction of exocytosis in cAMP-treatedcells was between –50 and –20 mV (p < 0.05, Fig.4, B and C, right panels), whereas the effect was not significantin control RCCs (p > 0.1, left panels). Nevertheless, Ni²⁺partially blocked the quantity of charge and secretion alsoin cAMP-untreated RCCs. This was more evident above +10 mV andattributed to a partial depression of residual R-type channelsin control RCCs. Taken together, the results of Fig. 4 suggestthat the "low-threshold" exocytosis associated with cAMP-recruitedT-type channels exhibits the same sensitivity to Ni²⁺ of Ca_V3.2channels.

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FIGURE 4 Quantity of charge and secretion recruited by cAMP is sensitive to Ni²⁺. The T-type channel blocker Ni²⁺ (50 µM) has no effect on cAMP untreated cells, whereas it significantly reduces both Ca²⁺ currents and secretion after the long-term cAMP treatment. RCCs were pretreated with ${omega}$ -toxins and nifedipine. (A) Representative traces for a cell depolarized at –20 mV. Left, cAMP-untreated cell; right, cAMP-treated cell. (B and C) Mean quantity of charge and mean secretory responses evaluated between –50 and +40 mV depolarizations. Ni²⁺ significantly reduced both the Ca²⁺ charge and the capacitance increases after cAMP treatment.

Long-term cAMP treatment does not affect the density of R- and L-type currents and their related exocytosis
Having established that cAMP-recruited T-type channels producesizable exocytosis (Figs. 2 and 3), we next investigated whetherlong-term cAMP treatments had any effect on the exocytosis associatedto R and L types or whether they could affect the efficiencyof the secretory apparatus. The latter occurs after brief applications(30 min), in which cAMP acts as an amplification factor forexocytosis regardless of the channel type carrying Ca²⁺ (14

Fig. 5 shows that in ${omega}$ -toxin-treated RCCs bathed in solutionscontaining 50 µM Ni²⁺ and 1 µM nifedipine to preserveonly functionally active R-type channels, long-term treatmentswith cAMP preserve the density of charge and the associatedsecretion. The quantity of charge measured from –50 to+40 mV was the same in control (n = 15) and with cAMP (n = 13)(p > 0.5) (Fig. 5 A) and the same was true for the depolarization-evokedexocytosis, measured in the same voltage range (Fig. 5 B, p> 0.5). Thus, long treatments with cAMP seemed to affectneither the density of R-type channels nor the associated exocytosis( $~$ 13 fF between 0 and +20 mV), which nevertheless contributedto $~$ 30% of the total secretion of RCCs, see Fig. 2 (14).

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FIGURE 5 Long-term treatment with cAMP does not affect R-type currents and the related secretion. In the presence of ${omega}$ -toxins, nifedipine, and Ni²⁺, the long-term treatment with cAMP is ineffective in potentiating both the toxin-resistant R-type channels and the corresponding secretory response. Quantity of charge (A) and capacitance increases (B) were evaluated between –50 and +40 mV.

Similarly, long-term treatments with cAMP were ineffective onboth exocytosis and quantity of charge when L- and R-type channelswere available, i.e., in the presence of ${omega}$ -toxins and Ni²⁺ inthe bath (Fig. 6, A and B). L-type currents and the relatedexocytosis were evaluated at +10 mV using conditioning prepulsesto –40 mV (14

) to further inactivate the contributionof N- and P/Q-type channels, which could still function afterwashout of toxins. Test pulses lasted 120 ms to recruit themaximum number of vesicles from the IRP. In both cases, cAMPaffected neither the quantity of charge nor the secretory response.After 120 ms pulses, the capacitance increase was 17.2 ±3.3 fF (cAMP) versus 15.1 ± 1.4 fF (control) and thequantity of charge was 1.0 ± 0.2 pC/pF (cAMP, n = 6)versus 1.1 ± 0.3 pC/pF (control, n = 10). These resultsdemonstrate that, as previously reported (25

), the L-type currentdensity also was insensitive to long-term cAMP treatments andthat $~$ 1.0 pC/pF of charge density induced $~$ 15–17 fF secretion,independently of the presence of cAMP. Thus, we can concludethat the effects of 3 days cAMP treatment on exocytosis areprimarily mediated by the expression of T-type channels andthat the long-term treatment with cAMP is ineffective in potentiatingexocytosis when either L-type or R-type are the only channelsavailable.

Long-term exposure to cAMP preserves the size of the IRP and the Ca²⁺ dependence of exocytosis
Having established that T-type channels contribute to the fastsecretory activity of RCCs at low voltages, we next studiedthe time course at which T-type channels contribute to the depletionof the IRP of vesicles that are mobilized during short depolarizations.We followed the method of Horrigan and Bookman (40) consistingof applying pulses of increasing duration to –20 mV andplotting ${Delta}$ C versus pulse duration. As shown in Fig. 7, A andB, the T-type channel-induced secretion possesses the same kineticfeatures of that produced by HVA channels in RCCs (14,40): 1),the time course of the depolarization-evoked exocytosis is exponential( ${tau}$ = 54 ms) and is well fit by a first order kinetic model (solidline), 2), the initial rate of exocytosis (464 fF/s) estimatedby fitting the two values at 10 and 20 ms decreases drasticallyat longer times, and 3), ${Delta}$ C saturates with prolonged depolarizationand the asymptote of the fit furnishes the size of IRP (21 fF).This value, however, should be considered an underestimate ofthe true IRP since saturation of ${Delta}$ C was also reached, not onlybecause of approaching complete mobilization of the IRP, butalso because of the fast inactivation of T-type currents thatlimits the quantity of charge for pulses >100 ms.

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FIGURE 7 Size of the IRP is preserved by the long-term cAMP treatment. (A) RCCs were pretreated with ${omega}$ -toxins and nifedipine, and depolarized with pulses of different length (from 10 to 150 ms) at –20 mV to evoke increasing secretion. (B) Plot of ${Delta}$ C increases versus the corresponding pulse length; data are averaged from 20 cAMP-treated cells like the one tested in panel A. The solid curve is an exponential fit with ${tau}$ = 54 ms and maximal value indicated by the asymptote (21 fF). The dashed line drawn to fit the first two points at 10 and 20 ms has a slope of 464 fF/s and indicates the initial rate of exocytosis. (C) Double pulse protocol for estimating the IRP size. Two depolarizations at –30 mV were applied consecutively after a 1 s interval to –100 mV, as illustrated. Test pulses lasted 160 ms for cAMP-untreated and 100 ms for cAMP-treated cells to allow comparing the secretion induced by equal quantity of charges in both conditions. Each pair of depolarization was repeated at least three times, and values of ${Delta}$ C were averaged for each cell. RCCs were not pretreated with ${omega}$ -toxins and nifedipine. (D) Bar histograms indicate for cAMP-untreated (solid bars) and for cAMP-treated cells (open bars), respectively, the calculated values of B_max (IRP size) (24

), the capacitance increment ${Delta}$ C₁, and the ratio ${Delta}$ C₂/ ${Delta}$ C₁ = (1 – p), with p indicating the probability of release.

To better estimate the size of the IRP in cAMP-treated and cAMP-untreatedRCCs, we used a double-pulse protocol (42

) that allowed maximalrecovery of inactivated T-type channels after pulses of 100ms at –30mV. Considering that recovery from fast inactivationof ${alpha}$ _1H channels is almost complete in 1.5 s at –90 mV (43

)and that refilling of the IRP proceeds at a rate 10 times slower( ${tau}$ = 10 s) (44

), we used double pulses of 100 ms separated byinterpulse intervals of 1.5 s (0.5 s at –80 mV for measuring ${Delta}$ C and 1 s at –100 mV to fully recover T-type channels;Fig. 7 C, bottom). Since Ca²⁺ currents at –30 mV in cAMP-untreatedcells were smaller with respect to cAMP-treated cells, the twopulses lasted longer in control cells (160 vs. 100 ms). In thisway, all the assumptions of the method were satisfied to a greatextent by 1), delivering pulses that mobilize a large fractionof the IRP, 2), injecting an equal quantity of charges at eachpulse, and 3), causing minimal vesicle refilling during thetwo pulses. Fig. 7, C and D, shows that the lower and upperlimits of the pool size ( ${Delta}$ C₁ and B_max) are not significantlydifferent in control and after cAMP treatment: the mean B_maxvaries between 33.2 ± 5.2 fF and 36.8 ± 5.1 fF(p < 0.5) for cAMP-untreated and cAMP-treated cells. Thesame is true for the ratio ${Delta}$ C₂/ ${Delta}$ C₁ (0.34 ± 0.09 vs. 0.41± 0.07; p < 0.5), which furnishes the probabilityof vesicle release ( ${Delta}$ C₂/ ${Delta}$ C₁ = 1 – p). Thus, cAMP-recruitedT-type channels do not alter the size of IRP and the probabilityof vesicle release. It is worth noticing, however, that duringinterpulse intervals of 1.5 s some degree (15%–20%) ofvesicle refilling is likely to occur. This would produce increasedvalues of ${Delta}$ C₂ and a consequent overestimate of B_max that shouldbe partially compensated by a 5%–10% physiological decreaseof Ca²⁺ charge during the second pulse. These drawbacks, however,would affect equally the estimate of IRP of both cAMP-treatedand -untreated cells (Fig. 7 D).

Finally, the Ca²⁺ dependence of exocytosis was evaluated byplotting the capacitance increases versus the correspondingquantity of charge (Fig. 8). As in BCCs (45) and other neuroendocrinecells (46), secretion in RCCs is roughly linearly related tothe quantity of charge Q, particularly for small quantitiesof Ca²⁺ charges (<30 pC), as in our case (14,40). Linearitybetween Ca²⁺ entry and exocytosis was observed up to 12 pC (solidsquares). Thus, we tested whether long-term treatments withcAMP changed the efficiency of excitation-secretion coupling(open circles). Fig. 8 A shows that the two ${Delta}$ C plots are positivelycorrelated with the quantity of charge through statisticallyindistinguishable linear regressions: 1.6 ± 0.1 fF/pCfor controls and 2.0 ± 0.1 fF/pC for cAMP-treated cells(p > 0.5). This suggests that long-term cAMP treatments donot alter the efficiency of exocytosis when T- and R-type channelscontribute to the total current. The same efficiency was observedwhen L-type channels were also available. In this case, RCCswere pretreated with ${omega}$ -toxins and tested in the absence of nifedipine,providing an increased quantity of Ca²⁺ charges which extendedthe range of linearity of excitation-secretion coupling (opentriangles in Fig. 8 B).

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FIGURE 8 T-type channels are coupled to exocytosis with the same efficacy of L- and R-type channels. (A) ${Delta}$ C increases versus the corresponding quantity of charge for cAMP-untreated (R-type channels, ${blacksquare}$ ) and cAMP-treated cells (T- plus R-type channels, ${circ}$ ). Linear regression gave 1.6 ± 0.1 fF/pC and 2.0 ± 0.1 fF/pC, respectively. Cells were pretreated with ${omega}$ -toxins, and nifedipine was in the bath. (B) Ca²⁺ dependence of exocytosis is compared for R-, T-, and L-type channels. Experimental data for cAMP-untreated cells ( ${blacksquare}$ ) and long-term cAMP-treated cells ( ${circ}$ ) are the same as in A. Data points ( ${triangleup}$ ) and linear regression relative to L-type channels are taken from Carabelli et al. (14

). Slope of straight line is 2.1 ± 0.1 (fF/pC).

Single exocytic events are unaffected by long-term exposures to cAMP
The contribution of unitary exocytic events was estimated byanalyzing the trial-to-trial variations between consecutivedepolarization-evoked capacitance increases through a modifiedprocedure of the method described by Moser and Neher (47

) andCarabelli et al. (14

). A total of $~$ 150 consecutive brief depolarizations(20 ms) at –20 mV were applied at 0.3 Hz and the correspondingcapacitance increase ${Delta}$ C was plotted versus time (Fig. 9, top).Typically, the RCCs that displayed sizeable exocytosis had rapidrundown of the secretory response (vesicle depletion) that leveledoff to a mean steady-state value after the first 20–25pulses. The variance of the "stationary fluctuations" ( Formula

) around the mean ( $<$ ${Delta}$ C $>$ ) was estimatedand used to calculate the size of the single secretory event( ${Delta}$ c) through the equation:

Formula 1 (1)
whichis derived by assuming 1), quantal release with binomial statisticsof vesicle release with p indicating the release probabilityper vesicle, and 2), ${Delta}$ C = N ${Delta}$ c p with N indicating the numberof vesicles in the IRP (47). Due to the limited Ca²⁺ entry duringdepolarization p is assumed to be very small (<0.2) and neglected.To compensate for the slow drift of the mean ${Delta}$ C, the sample variancewas calculated versus the averaged sample means of four consecutive ${Delta}$ C, "moving bins" (47). The value of Formula 1 was corrected for the background variance of C_m(), by subtracting from . At the conditions of our ${Delta}$ C measurements obtained by averaging50 ms segments of C_m before each current pulse (see Materialsand Methods), the estimated was on average 2.5 fF² in both cAMP-treated and -untreated cells.Since this value was $~$ 25% Formula 1 , this implies that regardless of cAMP treatment, not accountingfor would overestimate ${Delta}$ cby $~$ 30%.

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FIGURE 9 Single quantal size is not affected by the long-term cAMP treatment. (A₁ and B₁) ${Delta}$ C increases in response to 150 consecutive pulse depolarization applied at –20 mV and lasting 20 ms (0.3 Hz), in the absence of (A₁) and after cAMP (B₁) treatment. The horizontal lines indicate the period during which ${Delta}$ C values were used for calculating the mean quantal size ${Delta}$ C (see text). (A₂ and B₂) Variances of ${Delta}$ C increases, evaluated by moving bin analysis. (Inset) Mean value of single secretory events ( ${Delta}$ c) for control and cAMP-treated cells. ${Delta}$ C values were calculated from Eq. 1 by subtracting from Formula 1

the background variance of C_m ( Formula 1

) that was determined by off-line filtering to 125 Hz the 50 ms baseline noise preceding each ${Delta}$ C measurement.

Fig. 9 shows the results of the "stationary fluctuation" analysisin a typical untreated and cAMP-treated cell (panels A and B).There is a rapid decay of ${Delta}$ C in both cases due to vesicle depletionduring the first 25 pulses and stationary fluctuations of ${Delta}$ Caround the mean at later pulses. In cAMP-treated cells the meanstationary value was higher due to the contribution of T-typechannels, but also the sample variance was higher with respectto control cells, suggesting that ${Delta}$ c does not change significantlyduring cAMP treatment (1.0 ± 0.2 fF in n = 8 controlcells and 1.0 ± 0.25 fF in n = 10 cAMP-treated cells)(Fig. 9, inset). Notice that the present estimate of ${Delta}$ c is infairly good agreement with the previously reported size of singlesecretory events estimated using "nonstationary" fluctuationanalysis in the same preparation (0.9 ± 0.1 fF) (14

).This allows concluding that recruitment of T-type channels doesnot alter the elementary size of single secretory events.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

We have provided evidence that cAMP-recruited T-type channelsare effectively coupled to exocytosis in RCCs and that theycontribute to secretion with the same efficiency of HVA Ca²⁺channels (R, L, N, P/Q) commonly expressed in RCCs. As T-typechannels contribute to the exocytosis without changing the sizeof single secretory events and the Ca²⁺ dependence, it is likelythat the secretion induced by chronic exposures to cAMP is associatedto Ca²⁺ entering through newly recruited T-type channels ratherthan to downstream changes of the secretory machinery. The netresult is an increased fast exocytosis at low voltages associatedwith a selective increase of functioning T-type channels coupledto secretion.

In our case, 3–5 days exposure to pCPT-cAMP had no effectson the density of HVA Ca²⁺ channels (25), and we checked specificallythat long-term cAMP treatments did not alter HVA channel contributionto secretion (Fig. 6). This was of particular importance andfurnished convincing evidence that long-term cAMP treatmentshave totally different effects on Ca²⁺ currents and secretioncompared to short-term treatments (1 mM cAMP, 30 min). Shorttreatments double the secretion and enhance L-type currentsby only 20% (14). The increased secretion in this case is attributedto changes of the secretory machinery downstream of Ca²⁺ entry,due to an increased efficiency of release and a doubling ofthe size of single secretory events.

T-type channels contribute to exocytosis with the same efficiency of other HVA channels
Several lines of evidence indicate that in adult RCCs T-typechannels are effectively coupled to secretion: 1), there isstrict correlation between the voltage dependence of secretionand Ca²⁺ entry through T-type channels (Fig. 3), 2), Ni²⁺ effectivelyblocks T-type currents and the associated exocytosis (Fig. 4),and 3), in the presence of Ni²⁺ and ${omega}$ -toxins, cAMP is unableto affect the secretory response associated with L- and R-typechannels. This is in contrast to what is reported in embryonicRCCs in which the ${alpha}$ _1H T-type channels did not produce secretion(23). The discrepancy could be due to the lack of some criticalfactor associated to secretion in immature RCCs. Uncouplingcannot certainly depend on the lack of the "synprint" site onthe ${alpha}$ _1H subunit (36) that favors the coupling of N- and P/Q-typechannels to SNARE proteins (48). In fact, L-type channels, whichalso do not possess the "synprint" site, are effectively coupledto secretion in RCCs (14,16,49,50) and MPC 9/3L cells (33).Alternatively, the uncoupling could be the result of a lowerquantity of Ca²⁺ entry associated to a reduced expression densityof T-type channels in immature RCCs (6.5 pA/pF at –10mV in 10 mM Ba²⁺) versus a higher density in mature cAMP-treatedRCCs (10–20 pA/pF; at –10 mV in 10 mM Ca²⁺) (25)or to differences in the Ca²⁺ buffering system that plays acritical role in chromaffin cells, due to the significant distanceat which Ca²⁺ channels are located from release sites (200 nmon average) (17). It is worth noticing, however, that T-typechannels are effectively coupled to fast secretion in a numberof cell preparations, including melanotropes (31), INS-1 ß-cells(29), MPC 9/3L cells (33), and retinal bipolar cells (32), suggestinga constitutive functional role of T-type channels in controllingfast exocytosis in a variety of cells.

Our data clearly show that, similarly to L-type channels (14),the Ca²⁺ dependence of secretion associated with T-type channelsis roughly linear and remains unaltered in RCCs ( $~$ 2 fF/pC), indicatingsimilar couplings of the two channel types with the secretoryapparatus. In relation to this, there are two interesting pointsworth discussing. First, rough linearity between Ca²⁺ chargesand exocytosis is a property of several neuroendocrine cellsand some neuronal preparation (for review, see Kits and Mansvelder(46)). Either strict or rough linearity is reported in RCCs(14,16,40), BCCs (45), melanotropes (31), pancreatic ß-cells(51), pituitary cells (52), peptidergic nerve terminals (53),and sympathetic ganglia (54). Given this, the second interestingissue to consider is that changes in the steepness of the Ca²⁺dependence of secretion are usually associated with treatmentsaltering the process of vesicle fusion or vesicle trafficking,which usually affect the size of RRP (or IRP). This includesshort-term treatments with cAMP (14), mutations of Rab3A (45),acute application of dopamine (31), depletion of intracellularCa²⁺ stores (55), and overexpression of tomosyn, a syntaxin-bindingprotein (56), whereas alteration of channel densities (14,16,46),modulation of channel gating (18), or increments of Ca²⁺ fluxesvia Ca²⁺ channel agonists (51) do not alter the slope of Ca²⁺efficiency of release. Thus, it seems reasonable that recruitmentof newly synthesized T-type channels follows the general rulethat modifications of Ca²⁺ channel densities do not affect theCa²⁺ dependence of exocytosis in chromaffin cells.

The vesicle pool, probability of release, and rate of release associated with newly recruited T-type channels
Long-term treatments with cAMP preserve the size of the releasablepool, suggesting that newly recruited T-type channels mobilizevesicles from an IRP comparable to that controlled by HVA channels.We proved this by using the conventional double-pulse protocol(42), which furnished an IRP significantly higher than thatestimated with single pulses of increasing duration (36 fF vs.21 fF; Fig. 7, B and D). As the former can be considered anoverestimate and the latter an underestimate, the true IRP isreasonably expected around 30 fF, which is a value comparablewith the IRP controlled by HVA channels in RCCs (34 and 40 fF)(14,40) and mouse chromaffin cells (MCCs) (47 fF) (57). A secondimportant consideration is that T-type channels do not alterthe high probability of vesicle release with pulses of 100 ms(p $~$ 0.6). Similar values of p are reported in RCCs (14), BCCs(42), and MCCs (57) when L-, N-, and P/Q-type channels are theonly Ca²⁺ channels available. In line with this, it is worthnoticing that T-type channels induce remarkably fast exocytosiswith a high initial rate of release (466 fF/s), which is onlypartially smaller than the rate associated with HVA channelsin the same cell preparation (580 and 680 fF/s) (14,40). However,if as suggested (40) the rate of exocytosis depends on Ca²⁺channel density, the lower density of T-type channels with respectto HVA channels largely justifies the lower rate in cAMP-treatedRCCs (see below).

Having shown that T-type channels effectively contribute tothe depletion of immediately releasable vesicles, it cannotbe excluded that they also contribute to the release of thelarger RRP of vesicles that is defined as the pool of all releasecompetent vesicles estimated using photorelease of caged-Caor prolonged and repeated depolarizations. In RCCs the RRP isestimated to be $~$ 10 times the size of the IRP (330 fF; see Horriganand Bookmann (40)), whereas in MCCs, more recent estimates usingcaged-Ca compounds have set the size of IRP and RRP at 47 and205 fF, respectively (57). As the RRP is largely depleted duringrepeated stimulations lasting several hundreds of milliseconds,it is likely that even if T-type channels are associated withthis pool of vesicles their contribution would rapidly vanishgiven their fast and complete inactivation with pulses longerthan 100 ms (58). This peculiarity reinforces the notion thata major role for T-type channels is in the control of a smallpool of vesicles related to fast exocytosis and associated withtransient Ca²⁺ injections of 20 to 50 ms.

A final point worth considering is that the density of T-typechannels would hardly alter the overall arrangement of Ca²⁺channels controlling secretion in RCCs, assuming that the channelswill be uniformly distributed along the cell surface. In fact,from the peak current (Ip = 160 pA at –10 mV in 10 mMCa²⁺; E_Ca = +70 mV) (25), the single-channel conductance ( ${gamma}$ =1 pS), the probability of channel opening (p = 0.5) (58), andthe mean cell diameter (18 µm after 4 days in culture)we estimated a density of $~$ 4 channels/µm² for T-type channels,which is smaller than the HVA channel density (6 channels/µm²)derived from the data of Cesetti et al. (27) (Ip = 300 pA at+20 mV in 10 mM Ca²⁺, E_Ca = +70 mV) with ${gamma}$ = 2 pS and p = 0.5.This implies that channel density would increase from 6 to 10channels/µm² when the two channel types contribute simultaneouslyto secretion (between –10 and +40 mV), but it would belimited to four channels/µm² at lower voltages (from –50to –10 mV) when the T-type is the only channel controllingsecretion. Indeed, accounting for the driving force and forthe 50% lower ion conductance of T-type channels, the contributionof these channels to the total current at +20 mV is $~$ 1/3 of thatcarried by the HVA channels. Thus, it appears that newly recruitedT-type channels do not produce major changes to the overalldistribution of voltage-gated Ca²⁺ channels controlling secretionexcept that by activating at lower voltages they can initiateexocytosis at potentials near resting conditions.

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Long-term incubation with cAMP clearly has very different consequenceson the secretory response of RCCs compared with the acute treatments:brief exposure to pCPT-cAMP (1 mM, 30 min) causes a 100% increaseof the secretory response attributed to an increased IRP anda doubling of the size of single secretory events (14). Unlikethe short-term incubation, the long-term treatment preservesthe size of IRP and single secretory events. Interestingly,3 days treatment with cAMP also increases the quantity of releasedcatecholamines per vesicle (59), suggesting increased concentrationsof adrenaline and noradrenaline within the secretory granules.

Although understanding the physiological consequences of recruitingT-type channels and their related secretion is beyond the purposeof this work, it is worth noticing that upregulation of low-thresholdchannels and "low-threshold exocytosis" in RCCs may have drasticeffects on cell excitability and adrenal gland function. Infact, even though long-term cAMP treatments do not alter thefrequency of action potential generation during bursts, recruitmentof T-type channels significantly lowers the firing thresholdin RCCs (25). This could possibly increase the number of actionpotential bursts that appears to be one of the most criticalparameters regulating secretion in RCCs (60). In addition tothat, a sizeable "low-threshold secretion" as reported heremay help increase the release of catecholamines during sustainedcell activity. Under these circumstances, cAMP levels are likelyto remain elevated for long periods of time due to the positivefeedback that originates from the increased release of catecholamines(59) and the activation of ß₁-adrenoreceptors expressedin RCCs (27).

ACKNOWLEDGEMENTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

We thank Dr. C. Franchino for preparing the cell cultures.

This work was supported by the Italian MIUR (grant COFIN No.2005054435 to E.C.), the Regione Piemonte (grants No. A28-2005to V.C. and No. D14-2005 to E.C.), and the San Paolo IMI Foundation(grant to the NIS Center of Excellence).

FOOTNOTES

P. Baldelli's present address is Dept. of Experimental Medicine,Viale Benedetto XV, 3 I-16100 Genoa, Italy.

Submitted on July 29, 2005; accepted for publication November 29, 2005.

REFERENCES

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

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15. Mansvelder, H. D., and K. S. Kits. 1998. The relation of exocytosis and rapid endocytosis to calcium entry evoked by short repetitive depolarizing pulses in rat melanotropic cells. J. Neurosci. 18:81–92.[Abstract/Free Full Text]

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Low-Threshold Exocytosis Induced by cAMP-Recruited CaV3.2 (1H) Channels in Rat Chromaffin Cells

Low-Threshold Exocytosis Induced by cAMP-Recruited Ca_V3.2 ( ${alpha}$ _1H) Channels in Rat Chromaffin Cells