Abstract
It is known that the sustained depolarisation of adrenal medullary bovine chromaffin cells (BCCs) with high K+ concentrations produces an initial sharp catecholamine release that subsequently fades off in spite depolarisation persists. Here, we have recreated a sustained depolarisation condition of BCCs by treating them with the Na+/K+ ATPase blocker ouabain; in doing so, we searched experimental conditions that permitted the development of a sustained long-term catecholamine release response that could be relevant during prolonged stress. BCCs were perifused with nominal 0Ca2+ solution, and secretion responses were elicited by intermittent application of short 2Ca2+ pulses (Krebs-HEPES containing 2 mM Ca2+). These pulses elicited a biphasic secretory pattern with an initial 30-min period with secretory responses of increasing amplitude and a second 30-min period with steady-state, non-inactivating responses. The initial phase was not due to gradual depolarisation neither to gradual increases of the cytosolic calcium transients ([Ca2+]c) elicited by 2Ca2+ pulses in BBCs exposed to ouabain; both parameters increased soon after ouabain addition. Νifedipine blocked these responses, and FPL64176 potentiated them, suggesting that they were triggered by Ca2+ entry through non-inactivating L-type calcium channels. This was corroborated by nifedipine-evoked blockade of the L-type Ca2+ channel current and the [Ca2+]c transients elicited by 2Ca2+ pulses. Furthermore, the plasmalemmal Na+/Ca2+ exchanger (NCX) blocker SEA0400 caused a mild inhibition followed by a large rebound increase of the steady-state secretory responses. We conclude that these two phases of secretion are mostly contributed by Ca2+ entry through L calcium channels, with a minor contribution of Ca2+ entry through the reverse mode of the NCX.
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Introduction
In a classical experiment done at the perfused bovine adrenal gland, Baker and Rink [7] found that the sustained depolarisation of medullary chromaffin cells with a high potassium solution (K+) induced a sharp catecholamine release response that rapidly faded in spite of the fact that cell depolarisation persisted. The authors attributed such secretion decay to a probable inactivation of an as yet uncharacterised voltage-activated calcium channel current (ICa). The whole cell inward ICa of bovine chromaffin cells (BCCs) was first characterised at Erwin Neher’s laboratory [18]. By using selective blockers of calcium channel subtypes, we later on found that such current was contributed by three of the subtypes of voltage-activated calcium channels (VACCs) described in neurons [44], namely, 20 % L-type (α1D, Cav 1.3), 30 % N-type (α1B, Cav 2.2) and 50 % PQ-type (α1A, Cav 2.1) [2, 3, 20, 22, 50].
Three different VACCs expressed within the same chromaffin cell raise the relevant physiological question on whether they play different roles in controlling various functions, particularly the calcium-dependent exocytotic release of catecholamine and the calcium-dependent endocytotic process [23, 37]. The following findings support some specific characteristics and different functions for channel subtypes [37]: (i) N and PQ currents are regulated by neurotransmitters in a voltage-dependent manner while L current regulation is voltage-independent [1, 21, 28]; (ii) depending on the experimental conditions, exocytosis triggered by K+ pulses may be preferentially coupled to L channels [36] or to PQ channels [33]; (iii) secretion triggered by trains of action potentials is controlled by PQ channels while with depolarising pulses, other channels participate [12]; (iv) the calcium-dependent endocytosis is mostly controlled by L channels [49, 51]; (v) N and PQ channels undergo a pronounced voltage-dependent inactivation while L channels are resistant to such inactivation [29, 56]; (vi) L channels undergo calcium-dependent inhibition at a rate slower than N and PQ channels [30]; (vii) calcium entering the cell through the lesser inactivating L channels serves to modulate the more inactivating N and PQ channels [50].
The simple picture on the role of calcium in the stimulus-secretion coupling process [14] was based in the pioneering experiment of Douglas and Rubin [16] in the perfused cat adrenal gland: the acetylcholine-triggered secretion required external Ca2+ entry through a Ca2+-permeable membrane pathway [15]. However, we now know that Ca2+ ions intervene not only in the final steps of exocytosis but also at pre-exocytotic steps. In this context, the early supposition of Baker and Rink [7] in the sense that the transient secretory response triggered by sustained K+ depolarisation of BCCs undergo inactivation, could certainly find a partial explanation in the voltage- and calcium-dependent inactivation of VACCs and of Ca2+ entry, as suggested by these authors. However, in the context of new knowledge accumulated since 1975, the inactivation of secretion occurring in spite of sustained depolarisation may be better explained by including additional factors. For instance, not all channel subtypes inactivate similarly, as discussed above. Thus, in perifused BCCs, we found that sustained K+ depolarisation caused a secretory response with two components. One accounted for 70–80 % of the secretory response and was blocked by ω-conotoxin GVIA (GVIA) and ω-agatoxin IVA (IVA) and by sustained depolarisation; therefore, it was linked to Ca2+ entry mostly through N and PQ channels. The other component was sensitive to 1–4-dihydropyridines and was resistant to inactivation, generating a low rate but sustained secretion [57]. Thus, it seems that sustained K+ depolarisation triggers a secretory response in BCCs with a fast initial peak component associated to inactivating N and PQ channels that fades off to reach a lower secretion steady-state plateau, sustained by Ca2+ entry through non-inactivating L channels.
The present study focuses on this problem with two major new experimental approaches: (1) instead of K+, the cardiac glycoside ouabain was used to elicit depolarisation of BCCs through the inhibition of the membrane Na+/K+-ATPase (NKA) [6]; and (2) instead of room temperature, the secretion experiments were performed at 37 °C because at this physiological temperature, higher rates of exocytosis have been reported to occur in BCCs [9, 25, 27, 32, 46, 59]. We here report that in BCCs perifused in a 0Ca2+ solution containing ouabain, the intermittent application of 2 mM Ca2+ pulses caused increasing secretory responses that reached a steady-state, non-inactivating plateau in about 30 min. Such responses were mostly due to Ca2+ entry through L channels although a minor contribution of the plasmalemmal Na+/Ca2+ exchanger (NCX) was also present. Considering that an endogenous ouabain-like steroid is known to be synthesised into and released from the bovine adrenal cortex [31, 52], our present results may have further physiological relevance in the sense that endogenous ouabain could somehow contribute to the maintenance of a long-lasting catecholamine release response during prolonged stressful conflicts.
Materials and methods
Isolation and culture of bovine chromaffin cells
All experiments were carried out in accordance with the guidelines established by National Council on Animal Care and were approved by the local Animal Care Committee of the Universidad Autónoma de Madrid. Bovine adrenal glands were obtained from a local slaughterhouse under the supervision of the local veterinary service.
Chromaffin cells were isolated following standard methods [35] with some modifications [41]. Cells were suspended in Dulbecco’s modified Eagle’s medium (DMEM) supplemented with 5 % foetal calf serum, 10 μM cytosine arabinoside, 10 μM fluorodeoxyuridine, 50 IU mL−1 penicillin and 50 μg mL−1 streptomycin. For catecholamine secretion experiments, cells were plated on plastic Petri dishes (60 mm) at a density of 106 cells mL−1 (5 mL per dish). For measurements of ionic currents with the patch-clamp technique, cells were plated on 1-cm diameter glass coverslips at a density of 5 × 104 cells/coverslip. Cells were kept for 1–4 days at 37 °C in a water-saturated incubator, with a 5 % CO2/95 % air atmosphere. After 24 h, the medium was replaced by serum-free fresh medium, and subsequently changed every 2 days.
On-line measurement of catecholamine release from intact bovine chromaffin cell populations
Cells were scrapped off carefully from the bottom of the Petri dish with a rubber policeman and centrifuged at 800 rpm for 10 min. The cell pellet was resuspended in 200 μL of Krebs-HEPES (composition in mM: NaCl 144; KCl 5.9; MgCl2 1.2; glucose 11; HEPES 10; pH 7.4); the concentration of CaCl2 varied depending on the protocol. Cells were introduced in a microchamber for their superfusion at the rate of 2 mL min−1.
The microchamber had a volume of 100 μL and was covered with a jacket for the continuous external circulation of water at 37 °C. For the detection of released catecholamines, the liquid flowing from the superfusion chamber reached an electrochemical detector (model Metrohn AG CH-9100 Herisau, Switzerland) equipped with a glassy carbon working electrode Ag/AgCl reference electrode and a gold auxiliary electrode. Catecholamines were oxidised at +0.65 V, and the oxidation current was recorded on a PC computer placed just at the outlet of the microchamber, which monitors on line, under the amperometric mode, the amount of catecholamines secreted [11]. Cells were stimulated to secrete with 10-s pulses. Solutions were rapidly exchanged through electrovalves commanded by a computer.
Recording of calcium channel currents
Membrane currents were measured using the whole cell configuration of the patch-clamp technique [26]. Coverslips containing the cells were placed in an experimental chamber mounted on the stage of a Nikon Diaphot inverted microscope. The chamber was continuously perfused with a control Tyrode solution containing (in mM): NaCl 137, MgCl2 1, CaCl2 2, HEPES/NaOH 10, pH 7.4. For current recordings, 2 mM Ca2+ was used as charge carrier. The cells were internally dialysed with a solution containing (in mM): NaCl 10, CsCl 100, tetraethylammonium.Cl 20, MgATP 5, 3-ethyleneglycol-bis-(α-aminoethylether)-N,N,N′,N′-tetraacetic acid (EGTA) 14, N-(2-hydroxyethyl) piperazine-N′-(2-ethanesulfonic acid) (HEPES)/CsOH 20, Na.GTP 0.3, pH 7.2.
Whole cell recordings were made with fire-polished glass electrodes (resistance 2–5 MΩ) mounted on the headstage of an EPC-9 patch-clamp amplifier, allowing cancellation of capacitative transients and compensation of series resistance. All recordings and data analysis were carried out with the software PULSE (HEKA Elektronik, Lambrecht, Germany). Unless indicated otherwise, the cells were clamped at −80 mV holding potential. Step depolarisations to 0–10 mV from this holding potential lasted 50 ms and were applied at 30-s intervals, to minimise current rundown [19]. Cells with pronounced rundowns were discarded.
External solutions were exchanged by a fast superfusion device consisting of a modified multi-barrelled pipette, the common outlet of which was positioned 50–100 μm from the cell. Control and test solutions were changed using miniature solenoid valves operated manually (The Lee Company, Westbrook, CT, USA). The flow rate (0.5–1 mL min−1) was regulated by gravity to achieve a complete replacement of cell surroundings in less than 1 s.
Recording of membrane potential and action potentials
Recordings of membrane potential (Vm) and APs were made under the current-clamp mode in the whole cell configuration of the patch-clamp technique [26], which allows the observation of spontaneous variations in the Vm.
Cells were superfused with control Tyrode solution at pH 7.4 containing (in mM): 137 NaCl, 1 MgCl2 and 10 HEPES/NaOH; an intracellular solution at pH 7.4 containing (in mM) 135 KCl, 10 NaCl, 10 HEPES, 1 MgCl2 and 5 EGTA was introduced in the patch-clamp pipette.
Measurement of cytosolic calcium concentrations
The changes of the cytosolic calcium concentrations ([Ca2+]c) triggered by Ca2+ pulses were monitored using the fluorescent Ca2+ probe fluo-4. Two-day post-plated cells at a density of 2 × 105 cells per well on 25-mm diameter Petri dishes were loaded with 3 μM fluo-4/AM for 45 min at 37 °C in Krebs-HEPES solution containing the following composition (in mM): 140 NaCl, 5.6 KCl, 1.2 MgCl2, 2 CaCl2, 10 HEPES, 11 D-glucose, pH 7.4. Loading with fluorescent dye was terminated by washing the Petri dishes, containing the attached cells, twice with Krebs-HEPES; then, cells were kept at room temperature for 15 min before placing them in the head stage of a Nikon eclipse TE-300 microscope equipped with shutter lambda 10–2 filter wheels instrument (Shutter instruments Co. Novato, CA, USA) to measure their fluorescence. Fluo-4 was excited with light at 485 nm. Emitted light was transmitted through a 505-nm dichroic mirror and a 520-nm barrier filter before being detected by a Hamamatsu cooled CCD-camera Orca-G (Hamamatsu Photonics Inc., Higashi-Ku, Hamamatsu City, Japan). Data were acquired and analysed using the Metafluor v 2.2 Imaging System (Molecular Devices).
Materials and solutions
The following materials were used: collagenase type I from Sigma (Madrid, Spain); Dulbecco’s modified Eagle’s medium (DMEM), bovine serum albumin fraction V, foetal calf serum, and antibiotics were from Gibco (Madrid, Spain). All other chemicals used were reagent grade from Merck and Panreac Química (Madrid, Spain). Agatoxin-IVA was from PeptaNova GmbH (Sandhausen, Germany), and ω-conotoxin GVIA was from Bachem Feinchemikalien (Budendorf, Switzerland). Agatoxin-IVA and ω-conotoxin GVIA were dissolved in distilled water and stored frozen in aliquots at 0.1 mM. Nifedipine (10−2 M) was prepared in dimethylsulphoxide (DMSO) and protected from light. Final concentrations of drugs were obtained by diluting the stock solutions directly into the extracellular solution. At these dilutions, solvents had no effect on the parameters studied.
Statistics
The results are presented as means ± SEM. The measurements of peak current and charge that flow through the channels after their activation were calculated with the programme PULSE. IC50 values were estimated through non-linear regression analysis using OriginPRO software (OriginLab Corporation, Northampton, USA). Data analysis of amperometric recording in BCC populations (peak amplitudes in nA or areas in pC) was performed using OrigingPro software. Data from measurement of changes in the [Ca2+]c were acquired and analysed using the Metafluor v2.2 Imaging System (Molecular Devices, Sunnyvale, CA 94089 USA). Graphs and the mathematical analyses were performed using the GraphPad Prism software, version 5.01 (GraphPad Software Inc., La Jolla, CA, USA). Comparisons between means of group data were performed by one-way analysis of variance (ANOVA) followed by the Duncan post hoc test when appropriate.
Results
This study was aimed at exploring the secretory responses elicited by Ca2+ pulses and the contribution of plasmalemmal VACC subtypes and the NCX to those responses, in BCCs chronically exposed to 10 μM ouabain to block the sodium pump at 37 °C. This physiological temperature was selected because the secretory responses of chromaffin cells are substantially higher at 37 °C, compared with room temperature used by most researchers in this field. Thus in spite of the fact that temperature does not affect ICa currents in BCCs, the K+ secretory responses are 3-fold higher at 37 °C, with respect to 22 °C [46]. The secretion experiments here presented were done in BCCs that were continuously fast-perifused with Krebs-HEPES at 37 °C, containing nominal 0Ca2+ in the presence of 10 μM ouabain. This ouabain concentration was chosen on the basis of previous experiments showing that it caused near full inhibition of the NKA in BCCs [6]. The 0Ca2+ solution prevented the development of an increased basal secretion known to occur in incubated ouabain-treated BCCs [6].
Secretory responses triggered by repeated calcium pulses: effects of ouabain, nifedipine, ω-toxins and FPL64176
In a classical experiment from the laboratory of William Douglas, the Ca2+ pulse protocol was used to demonstrate that after a period of perfusion with saline deprived of divalent cations (i.e. Mg2+ and Ca2+), the introduction of Ca2+ triggered a healthy catecholamine release response in the perfused cat adrenal gland [17]. In the case of BCCs (5 millions trapped in a microchamber) that were being perifused in nominal 0Ca2+ (in the presence of Mg2+ at 1.2 mM), the repeated applications of 2 mM Ca2+ pulses for 10 s at 3-min intervals produced a tiny secretion that was maintained at around 20 nA along 1 h and 21 sequential 2Ca2+ pulses (Fig. 1a). Those responses could be generated by tiny Ca2+ entry through store-operated Ca2+ channels (SOC) that could be activated by partial depletion of the endoplasmic reticulum (ER) Ca2+ store in cells that were being perifused with 0Ca2+ during the 2Ca2+-pulse intervals. It could also be due to Ca2+ entry through the reverse mode of the plasmalemmal NCX.
In a similar experiment and after the initial application of six sequential 2Ca2+ pulses, ouabain at 10 μM was perifused; the secretory responses began to increase in amplitude to reach a plateau at around 200 nA after giving 11 additional 2Ca2+ pulses (30 min in the presence of ouabain). In the last 6–7 pulses, still in the presence of ouabain, the secretion responses reached a steady-state plateau (Fig. 1b).
Experiments to test the contribution of VACC subtypes were next performed using selective blockers of L channels (10 μM nifedipine) or combined blockers of N channels (1 μM GVIA) and PQ channels (3 μM IVA). In the experiment of Fig. 1c, once the secretory responses stabilised at around 150 nA, the introduction of nifedipine on top of ouabain drastically reduced the response to near pre-ouabain levels (Fig. 1c).
In the experiment of Fig. 1d, the BCCs were preincubated with the ω-toxins for 45 min because their expensiveness precluded their continuous application in the medium that perifused the cells. These toxins are known to irreversibly bind to N and PQ channels [3, 30], and thus, we assumed that in the present experiments, they are blocking the N and PQ channels. In spite of this channel blockade, in the ω-conotoxin-treated BCCs, the Ca2+ pulses still elicited large secretory responses at around 200 nA, similar to those of previous experiments (Fig. 1d). In an additional experiment, the ω-conotoxin-preincubated cells were challenged with 2Ca2+ pulses, and once the steady state of secretion was reached at around 270 nA, nifedipine was added on top of ouabain; once more, nifedipine caused a rapid and drastic blockade of secretion (not shown). It was interesting that nifedipine brought the steady-state response to the initial levels, suggesting that this tiny response was not associated to Ca2+ entry through L-type VACCs; as stated before, such responses could be due to tiny Ca2+ entry through the reverse NCX. The time courses of the averaged secretory responses in cells treated with ouabain alone or ω-toxins plus ouabain are plotted in Fig. 1e; they were similar. Averaged data are graphed in Fig. 1f; ouabain augmented secretion at a peak of 220 ± 35 nA, 10-fold higher than the initial secretion. Nifedipine reduced secretion to near initial values both in cells treated only with ouabain and in those preincubated with ω-toxins and subsequently treated with ouabain.
Similar experiments with L channel activator FPL64176 [39] were performed next. In the experiment displayed in Fig. 2a, ouabain augmented the secretory responses elicited by repeated 2Ca2+ pulses that reached a steady-state peak secretion at around 200 nA. Added on top of ouabain, FPL64176 at 0.3 μM caused a notable further increase to a new steady-state level of secretion, at around 400 nA. Finally, when added on top of ouabain and FPL64176, nifedipine at 10 μM near fully blocked the secretory responses. Pooled data are graphed in Fig. 2b. Ouabain augmented by 10-fold the initial secretion that was further enhanced by 18-fold in the presence of ouabain plus FPL64176 and was reduced to the initial level of secretion by nifedipine.
Secretory responses triggered by repeated potassium pulses: effects of ouabain, nifedipine and ω-toxins
As the potentiation of secretion was likely due to the indirect cell depolarising effects of ouabain, it was of interest to see whether such potentiation was produced also when the cells were challenged with a K+ pulse to elicit a direct cell depolarisation. In fact, in cells perifused with a 2 mM Ca2+ solution, we previously found that secretion triggered by 10-s pulses of a Krebs-HEPES solution containing 35 mM K+ and 2 mM Ca2+ (35 K+/2Ca2+) was gradually enhanced in BCCs treated with ouabain [40]. Thus, we explored here how the ω-toxins and nifedipine affected such responses in cells that were continuously perifused with 0Ca2+ and ouabain. The experimental designs were similar to those described in Fig. 1 for the 2Ca2+ pulses, and the 35K+/2Ca2+ pulses were applied for 10 s at 3-min intervals.
Figure 3a displays a record from an experiment in which the BCCs were repeatedly challenged with 35K+/2Ca2+ pulses, showing tiny secretory responses of around 20–25 nA. In the experiments of Fig. 3b, the introduction of 10 μM ouabain from the 5th 35K+/2Ca2+ pulse onwards gradually augmented the secretory responses that reached a plateau at around 100 nA at the 12th 35K+/2Ca2+ pulse given in the presence of ouabain. In a similar experiment, the introduction of 10 μM nifedipine reduced back the augmented secretion responses to pre-ouabain levels (Fig. 3c). Furthermore, in cells preincubated with ω-toxins (as in Fig. 1d, e), the augmentation by ouabain of the responses to the 35K+/2Ca2+ pulses was unaffected (Fig. 3d); additionally, in these ω-toxin-treated cells, nifedipine still produced a drastic reduction of the 35K+/2Ca2+ responses that had been previously augmented by ouabain (Fig. 3e).
Pooled averaged data from experiments performed with those distinct protocols are summarised in Fig. 3f. Ouabain augmented the 35K+/2Ca2+ secretion response from 22 ± 2.5 to 180 ± 12 nA; nifedipine reduced the response to 30 ± 1.6 nA. In BCCs preincubated with ω-toxins, ouabain caused a similar augmentation of secretion (194 ± 16 nA), and this response was reduced by nifedipine to 35 ± 1.2 nA. In brief, the effects of ouabain, nifedipine and ω-toxins seemed to be quite similar with the two patterns of stimulation of the BCCs, namely, 2Ca2+ pulses (Fig. 1) and 35K+/2Ca2+ pulses in BCCs continuously perifused with a 0Ca2+ solution (Fig. 3).
Secretory responses triggered by calcium pulses: effects of compounds KB-R7943 and SEA0400
As mentioned in the “Introduction”, the inhibition of NKA by ouabain increases [Na+]c and activates the reverse mode of the NCX (rNCX) [10]. KBR [60] has been widely used to block the NCX; however, this compound has poor selectivity and targets other ion channels and transporters, i.e. the native nicotinic receptors α3β4 of BCCs as well as the α3β4 and α7 nicotinic receptors expressed in oocytes [48]. Later on, the more selective and potent NCX blocker SEA appeared [38]. Thus, we felt of interest to test the effects of these two NCX blockers on the secretion elicited by 2Ca2+ pulses in ouabain-treated BCCs perifused with 0Ca2+ at 37 °C. It is known that in chromaffin cells, the Na+/Ca2+ co-transport through the NCX is 5-fold higher at 37 °C with respect to room temperature [47, 55].
In the experiments of Fig. 4a, the initial secretion elicited by 2Ca2+ pulses of about 20–25 nA was gradually enhanced by 10 μM ouabain to reach a plateau of around 230 nA. Added on top of ouabain, KBR at 10 μM drastically reduced the responses to the initial level; upon KBR washout, the secretory response recovered the ouabain-plateau levels. A similar experiment was performed with SEA (Fig. 4b). Once more, ouabain caused a gradual increase of the secretory response elicited by the 2Ca2+ pulses that reached a plateau at around 220 nA. Added on top of ouabain, SEA at 10 μM elicited a mild decrease of secretion (from 220 to 200 nA); surprisingly and opposite to KBR, after SEA washout, a pronounced rebound increase of secretion occurred. In these experiments, ouabain was removed from the perifusion fluid together with the NCX blocker; however, it is well established that the ouabain effects on secretion remain for a long time after its washout [24].
Pooled data graphed in Fig. 4c indicate that the initial secretion elicited by 2Ca2+ pulses augmented to 245 ± 22 nA upon ouabain treatment (10-fold increase). Added on top of ouabain, KBR drastically reduced the response to 30 ± 7 nA. This response recovered the previous ouabain peak upon KBR washout. In the case of SEA, it was noteworthy that the peak ouabain response of 237 ± 18 nA was reduced to 189 ± 17 nA, but this effect was not statistically significant. Upon SEA washout, however, secretion reached a peak of 335 ± 32 nA, a significant increase.
Effects of compound KB-R7943 and SEA0400 on sodium and calcium currents
Because of the above-mentioned limited selectivity of KBR to block the NCX, it was convenient to study its ability to block sodium and calcium currents (INa, ICa) in voltage-clamped cells. Inward whole cell currents were generated by 50-ms test pulses to 0 mV, applied from a holding potential of −80 mV. The first fast inactivating component of the current was due to Na+ entry (INa), and the second noninactivating component was due to Ca2+ entry (ICa) (Figs. 5a, c, arrows).
In the experiment of Fig. 5a, after current stabilisation with repeated test pulses, the successive application of 1 and 10 μM KBR caused a tiny reduction of INa and ICa. On quantitative terms, such reduction accounted for 20 % for INa and 30 % for ICa at 10 μM of KBR (Fig. 5b). Given that in BCCs, the L channel component of ICa accounts for about 20 %, and the fact that KBR near fully blocked the secretion responses elicited by 2Ca2+ pulses, it seems reasonable to suspect that at 10 μM, KBR is selectively blocking the L-type VACCs of BCCs. This was corroborated by occlusion experiments done with nifedipine and KBR. We found that nifedipine occluded the blocking effect of KBR and that KBR occluded the blocking effect of nifedipine (Fig. 6).
Figure 6a shows the time course of ICa (ordinate in pA) and the time-dependent blockade by about 20–25 % elicited by 10 μM nifedipine; on the stabilised new current plateau level, the addition of 10 μM KBR on top of nifedipine did not cause further blockade. The washout of both compounds elicited a gradual current recovery. Figure 6b shows original ICa traces (note the initial fast inactivating Na+ current); the control ICa was reduced by around 20 % by nifedipine, and the KBR added on top of it did not cause further blockade. Conversely, when KBR was added first, nifedipine did not elicit further current blockade. Averaged pooled data on Ica blockade elicited by nifedipine or KBR, when added separately or in combination, are plotted in Fig. 6d, e. Note the occlusion by each compound of the current blockade elicited by the other.
In the experiment of Fig. 5c, we explored whether 1 and 10 μM SEA affected INa or ICa. Neither in this example experiment nor in averaged experiments from different cells (Fig. 5d) did SEA affect INa or ICa.
Effects of ouabain on the membrane potential
Through the inhibition of NKA, ouabain should favour the accumulation of Na+ ions in the cytosol, thereby altering the Na+ gradient across the plasmalemma and causing its depolarisation. Whether ouabain also elicited BCC depolarisation was explored with the patch-clamp technique in its current-clamp mode under the whole cell configuration, using a nominal 0Ca2+ solution.
In the example record of Fig. 7a, the initial resting membrane potential (Vm) of the cell was around −50 mV; cell perifusion with 10 μM ouabain elicited a gradual depolarisation that reached around −35 mV in 2 min. It is interesting that after ouabain washout, the depolarisation persisted or even increased, as ouabain is known to stably bind to the membrane Na+/K+ ATPase [6]. In the cell of Fig. 7c, ouabain was added first, and then, 10 μM nifedipine was added on top of ouabain, showing no effect on the ouabain-elicited depolarisation. In 12 BCCs from 2 different cultures, ouabain produced a gradual depolarisation that amounted to 8 ± 1 mV after 3 min. In the presence of nifedipine and after washout, the depolarisation augmented by 18 ± 2 mV and by 28 ± 2.8 mV.
Elevation of the cytosolic calcium concentrations elicited by 2Ca2+ pulses in ouabain-treated BCCs
Changes in the [Ca2+]c transients elicited by 2Ca2+ pulses, before and during exposure to ouabain of fluo-4-loaded BCCs, were studied following protocols similar to those used to monitor secretion (Figs. 1 to 4). This could orient on a possible correlation between [Ca2+]c and secretion changes.
In the example [Ca2+]c record of Fig. 8a, the cell that was being perifused with 0Ca2+ was challenged with sequential 10-s pulses given with the 2Ca2+ solution at 3-min intervals. Ouabain at 10 μM, perifused from pulse 3 onwards, augmented the [Ca2+]c from around 12 arbitrary fluorescence units (AFU) to 25 AFU at pulses 3 and 4. This augmentation continued until pulse 7 that reached around 27 AFU; from this pulse onwards, the [Ca2+]c was maintained at values of around 30 AFU. In a similar experiment (Fig. 8b), ouabain more than doubled the amplitude of the [Ca2+]c transient while 10 μM nifedipine given on top of ouabain during pulses 8 to 10 drastically decreased the [Ca2+]c transient amplitude from 22 AFU to only 8 AFU. Upon nifedipine washout, the [Ca2+]c transient recovered its initial amplitude. Figure 8c shows a trace of [Ca2+]c transients produced by Ca2+ pulses in the presence of ouabain and the lack of effects of ω-toxins (combined ω-conotoxin GVIA at 1 μM and ω-agatoxin IVA at 1 μM). A graph summary of pooled normalised data from 24 cells is displayed in Fig. 8d. Note the drastic blockade exerted by nifedipine of these [Ca2+] c transients, the lack of effect of ω-toxins and again, the blockade by nifedipine in the presence of ω-toxins.
Discussion
The central finding of this study was the two-step time course of the catecholamine release responses triggered by repeated 2Ca2+ pulses applied to BCCs perifused with a 0Ca2+ solution containing ouabain: during the first 30 min, the initially tiny responses gradually increased to reach a stable steady-state plateau that lasted another 30 min. Because the BCCs exposed to ouabain underwent rapid depolarisation, we may reasonably conclude that the gradual delayed increase of secretory responses was not due to gradual cell depolarisation. This is corroborated by the observation that the secretory responses elicited by repeated 35K+/2Ca2+ pulses exhibited a gradual increase very much as that occurring with 2Ca2+ pulses: the 35K+-elicited depolarisation [45] did not contribute to produce further depolarisation in cells already depolarised by ouabain.
Concordant with rapid depolarisation of ouabain-treated cells were the [Ca2+]c transients elicited by repeated 2Ca2+ pulses that exhibited a plateau steady-state amplitude at few minutes after adding ouabain. Thus, we cannot attribute the gradual increase secretory responses to more Ca2+ entry with each 2Ca2+ pulse. Therefore, the rate limiting step in causing a delay to reach a steady-state secretion responses is neither gradual time-dependent depolarisation nor gradual increases of [Ca2+]c transient amplitudes. It may likely be due to a time-dependent increase of the rate of cytosolic vesicle transport from a large reserve pool of secretory vesicles (RP) toward a small subplasmalemmal ready-release vesicle pool (RRP) [42, 54]. In fact, using total internal reflection fluorescence microscopy (TIRFM), we found that ouabain favoured the accumulation of docked vesicles underneath the plasmalemma of BCCs [40].
Vesicle translocation from the RP to the RRP depends on mild elevations of the [Ca2+]c, which are subthreshold to trigger rapid exocytosis. This was first suggested at Neher’s laboratory that used mild depolarisations to increase Ca2+ entry through VACCs, or histamine to release Ca2+ from the endoplasmic reticulum store (ER) of BBCs [58]. Other experimental strategies that were later on used to augment Ca2+-dependent vesicle transport consisted in the stimulation with subthreshold nicotine [13], with acetylcholine pre-pulses [5] or the activation of the Ca2+-induced Ca2+ release mechanism present in BCCs [4] by ouabain [40]. In our present experiments, the BCCs were intentionally perifused with nominally 0Ca2+, and thus, the contribution of the ER Ca2+ would be minimal. Thus, Ca2+ entry through VACCs during the application of the 2Ca2+ pulses could likely be responsible for both, the pre-exocytotic acceleration of vesicle transport during pulse intervals and the rapid exocytosis occurring during the application of 2Ca2+ pulses.
Now, the question concerns the membrane pathway used by Ca2+ to enter the cell during the 2Ca2+ pulses. Chromaffin cells express various subtypes of VACCs [23, 37], including L, N and PQ channels. Near full blockade by nifedipine of the secretion triggered by 2Ca2+ pulses excludes the non-L, N/PQ VACCs as contributors to this secretory response; the experiments performed with ω-toxins that did not prevent the development of the ouabain-elicited gradual potentiation of secretion (Fig. 1d, e), strengthen the view that in ouabain-treated BCCs, the augmented secretion is attributable to a selective Ca2+ entry via L-type channels.
It is surprising that L-type channels remain open during the 60-min duration of an experiment using ouabain and the 2Ca2+-pulse protocol. This behaviour reminds that observed in a previous study also performed in BCCs that underwent sustained depolarisation with a 0Ca2+ solution containing 100 mM K+; when challenged with 100 mM K+ containing 2 mM Ca2+, these cells responded with a secretory response of around 150 nA that was near fully suppressed by nifedipine and drastically potentiated by FPL64176 and was unaffected by the combined treatment with ω-conotoxin GVIA and ω-agatoxin IVA [57]. Thus, it seems plausible that those earlier experiments with sustained K+ depolarisation of BCCs and the here reported experiments with ouabain have a similar underlying mechanism, namely, the voltage-dependent inactivation of N/PQ channels, while L channels exhibit an extraordinary resistance to voltage-dependent inactivation. The experiments with repeated 35K+ pulses in ouabain-treated cells, with secretion responses that are blocked by nifedipine but not by ω-toxins, also support this conclusion (Fig. 3).
That ouabain elicits that cell depolarisation was predictable on the basis of its ability to inhibit the plasmalemmal NKA, thus favouring the gaining of Na+ by the cell [53]. The current-clamp experiment of Fig. 7b illustrates the property of ouabain to elicit a prompt membrane depolarisation. Although this behaviour does not exactly reproduce the sustained cell depolarisation chemically produced by high K+ [57], it likely explains the selective inactivation of N/PQ channels, and the isolation of the L channel-linked selective Ca2+ entry pathway in BCCs under prolonged exposure to ouabain. This is supported by the observation that enhanced [Ca2+]c elicited by 2Ca2+ pulses in ouabain-treated BCCs was also truncated by nifedipine (Fig. 8b) and was unaffected by ω-toxins.
A physiological explanation for the gradual accumulation of secretory vesicles at subplasmalemmal exocytotic sites is compatible with the hypothesis of a feedback link between the size of the RRP and the rate and capacity of the vesicle transport machinery through the cytosol, towards subplasmalemmal regions. Furthermore, the steady state of the secretion responses reached after about 30-min application of 2Ca2+ pulses indicates that vesicle use and supply reached an equilibrium after 30 min of continued challenging of BCCs with the 2Ca2+ pulses. It may also suggest that vesicle use of the RRP during repeated cycles of exocytosis constitutes a positive feedback signal to gradually augment the rate of vesicle supply in the successive 2Ca2+ pulses. This equilibrium, however, does not mean that the size of the RRP has reached its limit, because in the presence of L-type VACC activator FPL64176, the secretion elicited by 2Ca2+ pulses near doubled.
Another point of physiological relevance is the potential contribution of the plasmalemmal NCX to the regulation of secretion in ouabain-treated BCCs. From a pharmacological optic, it was interesting that KBR fully blocked secretion (Fig. 4a); we attribute this effect to the blockade of L-channels that in BCCs, contribute about 20 % to the whole ICa [23]. The 20–30 % blockade of ICa elicited by KBR (Fig. 5b) may surely include the full blockade of L channels. In contrast, the more selective NCX blocker SEA-0400 that did not affect ICa (Fig. 5D), slightly decreased the secretory response elicited by 2Ca2+ pulses under ouabain, and elicited a rebound secretory effect upon its washout. This is compatible with a regulatory role of the NCX that under ouabain depolarisation should be working under its reverse mode, thus implying a greater Ca2+ entry through the reverse mode of the NCX and a greater secretion elicited by the 2Ca2+ pulses [46]. From a pharmacological point of view, our data on ICa suggest that KBR clearly blocks the L-type channels of BCCs while SEA did not; thus, SEA seems to be more selective to inhibit the plasmalemmal NCX and should preferably be used, instead of KBR to block such Ca2+ transporter.
We conclude with a physiological note. To favour vesicle flow towards subplasmalemmal and exocytotic sites, to replenish the empty RRP with new vesicles, a mild [Ca2+]c elevation seems to be required. This was fist experimentally tested either by applying to chromaffin cells mild depolarising pulses or through their challenging with histamine before evoking the exocytotic burst [58]. In this context, the experiments here reported are compatible with ouabain doing this task of causing mild [Ca2+]c elevations to augment vesicle flow and RRP refilling. Because the adrenal cortex is particularly rich in endogenous ouabain [34] and circulating ouabain is being considered as a hormone secreted by the adrenals as a pivotal factor in cardiovascular diseases [43], we are tempted to attribute physiological implications of the results here described. The physiological role may imply a chronic exposure of adrenal medullary chromaffin cells to adrenal cortical ouabain; this exposure in chronic stress situations in which a higher secretion of cortical ouabain could cause a mild depolarisation of the adrenal medullary chromaffin cells to maintain vesicle flow and secretion by Ca2+ entry through noninactivating L-type VACCs. In fact, circulating ouabain in humans is increasing upon physical exercise, although at nanomolar concentrations [8]. However, in the natural microenvironment of chromaffin cells that are exposed to cortical hormones, ouabain secreted from the adrenal cortex may locally reach higher concentrations to favour intracellular vesicle flow and the secretion of adrenaline during prolonged stress.
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Supported by a grant from MINECO (SAF 2013-44108-P). Also by CABYCIC, UAM/Bioiberica, Spain. We thank the continued support of Fundación Teófilo Hernando, Madrid, Spain.
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Ricardo De Pascual and Inés Colmena are equal contributors.
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De Pascual, R., Colmena, I., Ruiz-Pascual, L. et al. Regulation by L channels of Ca2+-evoked secretory responses in ouabain-treated chromaffin cells. Pflugers Arch - Eur J Physiol 468, 1779–1792 (2016). https://doi.org/10.1007/s00424-016-1866-x
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DOI: https://doi.org/10.1007/s00424-016-1866-x