©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Amperometric Detection of Quantal Secretion from Patch-clamped Rat Pancreatic -Cells (*)

(Received for publication, July 24, 1995; and in revised form, October 24, 1995)

Zhuan Zhou (§) Stanley Misler (¶)

From the Departments of Medicine (Jewish Hospital) and Cell Biology/Physiology, Box 8217, Washington University Medical Center, St. Louis, Missouri 63110

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

Serotonin (5-HT) is taken up in insulin granules and co-released with insulin on stimulation of pancreatic islet beta-cells. Based on these observations, we have used microcarbon fiber amperometry to examine secretogogue-induced 5-HT release from rat beta-cells preloaded for 4-16 h with 5-HT and then exposed to a bath solution containing 10 µM forskolin. In response to local application of KCl (60 mM) or tolbutamide (50-200 µM), we recorded barrages of amperometric events. Each amperometric event consisted of a short pulse of current measurable at electrode voltages that catalyze 5-HT oxidation. With either secretogogue, release was calcium-dependent. On combining amperometry with perforated patch whole-cell recording, we found that barrages of such events were well coupled in time and graded in intensity with depolarization-induced Ca currents and well correlated with increases in membrane capacitance. In cell-attached patch recording, amperometric events evoked by application of tolbutamide followed the closure of ATP-sensitive K channels and coincided with the onset of electrical activity. These experiments suggest that amperometry is a useful technique for studying, in real time, the dynamic aspects of stimulus-secretion coupling in beta-cells. Their performance was facilitated by the design of a new carbon fiber electrode (ProCFE) described within.


INTRODUCTION

Real time measurement of hormone release from endocrine cells, such as insulin-secreting beta-cells of the pancreatic islets of Langerhans, is critical for understanding stimulus-secretion coupling normally occurring in these cells, as well as defects in secretory function, such as those occurring in non-insulin-dependent diabetes mellitus. Recent advances in amperometry, a technique for the electro-oxidization of transmitter molecules near the surface of a cell, have permitted near instantaneous measurement of exocytotic hormone release(1, 2, 3) . In chromaffin cells, amperometry reveals that brief barrages of current spikes are evoked, in a calcium-dependent fashion, by several depolarizing stimuli, including nicotinic agents and high K(1) , brief voltage clamp pulses(2) , and even single action potentials(4) . Each spike corresponds to the near synchronous electro-oxidation of up to a million catecholamine molecules liberated from a point source on the cell surface(1) . In insulin-secreting pancreatic islet beta-cells, two early applications of amperometry to study secretion have been reported. In the first case, quantal release of insulin has been measured from glucose-, tolbutamide-, and high K-stimulated human islet cells based on the ability of a modified (ruthenate-coated) carbon fiber electrode to catalyze the electro-oxidation of S-S bonds between the A and B chains of insulin(5) . In the second case, secretogogue-induced quantal release of the ``false transmitter'' serotonin (5-HT), (^1)an electro-oxidizable indolamine sequestered and stored into insulin granules, has been measured from mouse beta-cells preincubated with 5-HT and 5-HT precursors(6) .

In this work, we have examined stimulus-secretion coupling in 5-HT-loaded rat beta-cells by combining patch clamp electrophysiology with amperometry. We demonstrate that this technique can be used to record exocytotic secretion simultaneously with secretogogue-induced electrical activity. Using this approach, we also present evidence for (i) the direct and rapid coupling of membrane depolarization to quantal secretion and (ii) aspects of the time course of the release of a quantum. This work has been facilitated by the recent design of a polypropylene-insulated carbon fiber electrode, or ProCFE. Its geometry, high sensitivity, low noise, and mechanical stability at physiological temperatures make it particularly advantageous for combined electrophysiological and electrochemical recording from beta-cells, which require minimum ambient temperatures of > 28 °C to insure secretion. Part of this data has been presented in abstract form (42) .


MATERIALS AND METHODS

Cell Preparation and Treatment

Rat islets, obtained by collagenase digestion of chopped pancreases of adult male Sprague-Dawley rats, were dispersed into a collection of cells using the enzyme dispase(7) . Cells were plated on glass coverslips and maintained at 37 °C in a modified CMRL medium (Life Technologies, Inc.) containing 10% heat-inactivated fetal bovine serum, 0.5% penicillin, and 0.5% streptomycin in the presence of 5% CO(2), 95% air for use within 2-5 days. Four to sixteen h prior to recording, 5-OH tryptamine (5-HT) and 5-OH tryptophan were added to the culture medium to final concentrations of 0.5-1 mM each. For recording, cells were placed in a temperature-regulated chamber (30-32 °C) filled with a physiological saline solution (PSS) consisting of 138 mM NaCl, 5.5 mM KCl, 2 mM CaCl(2), 1 mM MgCl(2), 3.0 mM glucose, and 20 mM HEPES buffer titrated with NaOH to 7.38 pH. Forskolin (10 µM) was added to the PSS to increase intracellular cyclic AMP and enhance depolarization-secretion coupling. To assess the Ca- dependence of release, the PSS was modified by reducing [CaCl(2)] to 0.1 mM and raising [MgCl(2)] to 2.9 mM.

Amperometric Measurements to Determine 5-HT Release

For amperometric measurements, two kinds of carbon fiber electrodes (CFEs) were used. A polyethylene-insulated CFE (peCFE) (4) modified from Chow et al.(2) was used for early amperometric recording (see Fig. 2and Fig. 3). A newly developed, low noise, polypropylene-insulated CFE (ProCFE) was used for all combined patch-clamp and amperometry experiments. Use of the ProCFE permitted mechanically stable amperometry at temperatures >30 °C required to optimize the chances for secretion. The CFE serves as the input to the head stage of the amperometry monitor, a patch-clamp amplifier, which in turn holds the CFE at a designated voltage. Test solutions containing secretogogues were applied by a puffer pipette consisting of a low resistance, glass capillary patch electrode pipette positioned within 50 µm of the cell.


Figure 2: Tolbutamide-induced quantal release from 5-HT loaded rat beta-cells: dependence on external Ca. Puffs of a modified PSS containing either 50 µM tolbutamide and 6 mM of Ca or 50 µM tolbutamide and no added Ca (free [Ca] < 20 µM) were alternately applied from a pair of puffer pipettes micropositioned to within 10 µm of opposite sides of this cell bathed in a modified PSS containing 100 µM Ca. Adjacent traces were separated by an 30 s interval during which no stimulation was delivered to the cell. In each case, the puff evokes a small positive plateau-like artifact that subsides at the end of the puff. (Puffer artifacts are often seen in electrochemical experiments. Sometimes they are upward; sometimes they are downward. We do not really know their origin, except to speculate that they represent the increase or decrease of oxidizable substances at the sensor surface introduced by puff.) Note that discrete amperometric spikes, representing rapid oxidation of a packet of 5-HT, were only seen in the case of 6 mM Ca.




Figure 3: High KCl-induced quantal release from rat beta-cells. In panel A, note that a puff of modified PSS containing 60 mM KCl and 6 mM Ca applied to a cell bathed in a PSS containing 0.1 mM Ca induced ASs with very short delay. In panel B, showing another cell bathed in a PSS containing 2 mM Ca, note that secretory response to the elevated KCl solution is dependent upon the holding potential of the CFE (V). ASs are absent during the puff when V was equal to 100 mV, but a clear barrage of events is seen when the same puff was applied at +680 mV. This is consistent with a threshold of 5-HT detection of 300 mV.



ProCFEs were fabricated by inserting a 2-cm segment of carbon fiber (5-7 µm diameter; Amoco Performance Products, Greenville, SC) into a 10-µl polypropylene pipetter tip (Continental Laboratory Products, San Diego, CA). The final 3-5 mm of the tapered end of the pipetter tip is then inserted into a 1.5-cm segment of 0.5 mm inner diameter plastic tube. With this maneuver, both ends of the pipetter tip could be grasped by two clamps. The tapered end of the pipetter tip was then heated to 430 °C by a soldering iron to melt the polypropylene onto the carbon fiber. To ``pull'' a ProCFE, force was exerted on both ends of the pipetter tip until the end of the carbon fiber was pulled out from the melted polypropylene end, forming a long ``exposed'' region of carbon fiber tip distal to the tapered insulation. For better reproducibility of ProCFEs, this heating and pulling process was done by a specially designed puller.

Prior to electrode use, the tapered tip of the carbon fiber was precisely cut to a length of 20-50 µm by micropositioning it at the crux of a spring-loaded, 7-10-mm iris scissors (Stolz Instrument Co., St. Louis, MO) mounted on the recessed surface of a magnetic stand base. This procedure reduced the chance of insulation defects near the cut edge, which, in turn, could provide leak pathways to ground and reduce the electrical potential at the sensor surface. The final taper length chosen was sufficient to reduce electrode noise, which is proportional to length, while providing the possibility of recutting the tip two or three times to continually optimize electrode sensitivity.

Fig. 1B presents a schematic of a CFE amperometry recording system. A sustained holding potential (V(c) usually = +780 mV) is applied to the CFE tip immersed in the bath. The equivalent circuit of a ProCFE, drawn as ``seen'' by the amplifier, is based on the observation that the additional capacitance of CFE, after it enters the bath, can be completely compensated by the ``fast'' and ``slow'' capacitance compensation function of an EPC-9 patch clamp amplifier. This suggests that the ProCFE, used in the amperometry mode, has an equivalent circuit similar to a cell recorded from in the ``whole-cell'' configuration(8) . The parameters in the equivalent circuit measured from six ProCFEs were as follows: R(b) = 56 ± 18 M; C(b) = 5.3 ± 1.1 pF; C(j) = 1.84 ± 0.44 pF; and R(j) >200 G. The peak-to-peak noise of the amperometric system using a ProCFE is 0.5-2 pA at a signal bandwidth of 1 kHz (average RMS-noise 0.164 pA, 0.1-1kHz 8-pole Bessel, n = 19). This was only about 2-7 times the base-line noise of the amplifier (EPC-7 or EPC-9).


Figure 1: Overview of amperometric recording. Panel A presents a sketch of a ProCFE with an expanded display of an insulated tip. The cone-like shape of the ProCFE resembles that of a 10-µl pipetter tip (30 mm in length). Panel B shows the equivalent circuit of an amperometry recording system with the CFE tip in the bath. V(c) is the applied holding potential. For amperometry, V(c) is a DC voltage of 650-800 mV. For voltametry, not used here, V(c) is a cyclic triangle wave. See text for other parameters.



Combined Amperometry/Perforated Whole-cell Recordings

These measurements were made from islet cells using techniques published previously for our lab(4) . Patch pipettes (resistance = 4-5 M) filled at the tip with a ``K-IS'' containing (in mM) 63.7 KCl, 28.35 K(2)SO(4), 47.2 sucrose, 11.8 NaCl, 1 MgCl(2), and 20 HEPES titrated to pH 7.3 with KOH and then back-filled with modified K-IS, which contained, in addition, 250 µg/ml nystatin. Electrical recordings were initiated once pipette access resistance fell to <35 M, which is usually within 1-5 min after formation of the seal(9) . Electrical activity and membrane currents, I(m), were evoked and recorded with an EPC-9 patch clamp amplifier (Heka Electronic, Lambrecht, Germany) controlled by an Atari computer. In the voltage-clamp mode, membrane currents were evoked by stepping the membrane potential (V(m)) from a holding potential of -70 mV to a given test potential. To evoke electrical activity in the current clamp mode, cells maintained at a V(m) of -70 mV through the application of a holding current up to -10 pA, were stimulated by depolarizing currents (+10 to +20 pA) applied for a variable duration. Data were acquired at sample rates up to 3 kHz using a Macintosh Quadra 650 computer running Pulse Control software(10) , which was connected to the patch clamp amplifiers via an ITC-16 A/D converter interface (Instrutech, Syosset, NY). Amperometric spikes (ASs) were analyzed, and histograms of their features were compiled using macros written by R. Chow and Z. Zhou using Igor software ( Wavemetrix, Lake Oswego, OR). All values from multiple experiments were given as mean ± S.D.


RESULTS

Secretagogue-induced Quantal Secretion of 5-HT from Single beta-Cells

Fig. 2, taken from an experiment typical of a series of 10, presents the salient features of amperometrically detected, stimulus-induced quantal release from intact beta-cells loaded with 5-HT. With the ProCFE positioned at the surface of a single islet cell bathed in a modified PSS containing 0.1 mM Ca, puffer application of PSS containing 50 µM tolbutamide, (^2)and 6 mM Ca, after variable delays of 5-30 s, repeatedly evoked a vigorous discharge of brief duration ASs. Each AS represents the total oxidation current of many 5-HT molecules released as a packet from an individual vesicle (see below). In contrast, intermittent puffs of PSS containing <20 µM free Ca and 50 µM tolbutamide were ineffective in evoking a response, suggesting that tolbutamide-induced quantal secretion is dependent on external [Ca](o). Note that with repeated puffs of the secretogogue, the average amplitude of the individual amperometric spikes declines.

Fig. 3A depicts a sample experiment from an extensive set (n = 20) showing that a PSS enriched in K also evokes quantal secretion from a 5-HT-loaded beta-cell. High K solutions are well known to rapidly depolarize beta-cells, initiate electrical activity and intracellular Ca transients, and provoke [Ca](o)-dependent insulin secretion. As in the case of tolbutamide, the occurrence of high K-evoked ASs was dependent on [Ca](o); no events were seen in a PSS containing 100 µM [Ca](o) (data not shown). Note that the delay time between the start of the high K puff and the initiation of the AS event was markedly shorter than seen with application of tolbutamide in Fig. 2. These experiments suggest that amperometric response to application of high K PSS provides a quick and simple way to check the integrity of depolarization-secretion coupling in single beta-cells. Fig. 3B provides evidence consistent with the substance underlying stimulus-induced ASs being 5-HT: high K-induced amperometric spikes are seen at a DC electrode potential (V(c) = +780 mV) sufficient to oxidize 5-HT but not at one (V(c) = +100 mV) far below the threshold oxidation potential for 5-HT. (^3)In the best batches, about 50% of cells displayed exocytosis in response to either tolbutamide or high K puffer solutions.

Quantitation of Quantal Release Events in Rat beta-Cells

Fig. 4demonstrates detailed features of individual amperometric spikes. Panels A-C show examples of these ``quantal'' release signals at expanded time scales. As seen in panels B and C, in many (>20%) low frequency quantal events, widely separated from others, the major spike is preceded by a small, brief (<50-ms duration) ``foot.'' These feet may be analogous to ``prefusion'' events recorded in chromaffin cells and mast cells (2, 3, 28) prior to the final expansion of the fusion pore connecting the granule and plasma membranes. Panels D-E tabulate peak amplitude (6.4 ± 4.5 pA), half-height duration (6.6 ± 6.1 ms), and total charge (Q) (56 ± 38 femtocoulombs) of amperometric spike events collected from 10 cells, where Q was calculated by integrating single amperometric currents over their time courses. Assuming (i) release is occurring from a point source under the large surface area electrode tip, hence permitting complete oxidation of all the transmitter molecules, and (ii) two or four electro-oxidations per molecule, (^4)Q can be used to estimate the number of 5-HT molecules oxidized in a near synchronous manner and hence provide an estimate of the number of molecules released in a quantal event; that is: 5-HT molecules/quantum = Q(coulombs/quantum) times (5-HT molecule/2 or 4 e) times (e/1.6 times 10 coulomb). From this, we estimate that, on average, as many as 0.88-1.76 times 10^5 molecules of 5-HT are released as a packet. While this quantity is substantially smaller than the 2.5 times 10^6 catecholamine molecules calculated to be released from a secretory granule of a chromaffin cell(1) , it is substantially larger than the 3.5 times 10^4 catecholamine molecules recently calculated to be released from a synaptic vesicle at an axon varicosity(11) .


Figure 4: Features of individual amperometric events. Panels A-C show examples of individual ASs. The arrows indicate small ``feet'' preceding fast major spikes; these are interpreted as ``leaks'' of the released substance before the secretory vesicle has fused completely into the plasma membrane(2, 4) . Panel D shows a histogram of transient integral, or total charge, associated with an individual amperometric event including foot and major spike. Panels E and D show histograms of amplitude and half-height duration of ASs. All histograms were constructed from same events collected from 10 cells stimulated by KCl.



Depolarization-secretion Coupling in Patch-clamped Cells

In the presence of 10 µM forskolin, we combined patch-clamp electrophysiology with amperometry to examine, in single beta-cells, the relationship of membrane depolarization to quantal release. It is assumed that these final steps of insulin secretion in beta-cells share many common features with depolarization-secretion coupling in neurons and other excitable endocrine cells, such as adrenal chromaffin cells.

Fig. 5demonstrates amperometric detection of quantal release evoked by prolonged membrane depolarization from a voltage-clamped cell. Rat beta-cells display high voltage-activated Ca currents detectable on depolarization to V(m) = -30 mV but reaching a peak value on depolarization of V(m) = +15 mV (see current trace in response to voltage ramp in right inset to panel A). Panel A demonstrates that repeated (3-s) pulses from a holding potential of -70 mV to a test potential of +10 mV evoke short bursts or intermittent individual amperometric events during the course of depolarization, although the quantal output declined with stimulus repetition (n = 11). From these experiments, it was clear that the quantal release was coupled with membrane depolarization. The first release events occurred with latencies as short as 30 ms after onset of the depolarization (left inset). In cells with higher and more stable rates of quantal release, it was possible to apply alternately several test potentials, evoking either a large or a small Ca current, and to combine amperometry with membrane capacitance (C(m)) tracking to assess exocytosis (see panel B). In beta-cells, Ca influx at -30 mV is nearly 10-fold smaller than at 5 mV (see Fig. 5A, inset). Note the absence of recognizable AS events or DeltaC(m) in response to a 5-s membrane depolarization to -30 mV that evoked barely measurable I. In contrast a barrage of amperometric spikes and a DeltaC(m) of 290 fF were generated in response to a 5-s membrane depolarization to +5 mV, a voltage that evokes a 6-7-fold greater I. This data, typical of those obtained from a set of three similar experiments, is consistent with the hypothesis that membrane fusion, as resolved by C(m), and quantal discharge of transmitter, as resolved by amperometry, reflect the same underlying fusion process determined by Ca entry into intact rat beta-cells. (^5)


Figure 5: Depolarization-induced quantal secretion from voltage-clamped cells. Panel A shows that repeated 3-s voltage-clamp pulses from -70 mV to +10 mV evoke barrages of ASs that are well coupled in time to intervals of depolarization. Here the cell was patched with a pipette containing a Cs-IS solution. The left inset shows the first barrage of evoked ASs at an expanded time scale. The right inset shows whole-cell current in response to a depolarizing voltage ramp from -100 to +100 mV over 100 ms. The shape of this current, with its peak at +15 mV, is nearly identical to the peak current-voltage characteristic of Ca current obtained with brief steps of depolarization in identical recording conditions (D. Barnett and S. Misler, unpublished data). Panel B shows the voltage dependence of secretion monitored simultaneously by amperometry and by tracking changes in membrane capacitance (C(m)). Note the absence of detectable ASs and DeltaC(m), with delivery of a 5-s pulse to -30 mV, when Ca influx was very small, as compared with the barrage of AS and nearly 300-fF increase in C(m), with delivery of a 5-s pulse to +5 mV, when peak I was more than 7-fold larger(36) .



Combination of amperometry with current clamp recording from patch-clamped cells permits examination of quantal secretion induced by electrical activity of beta-cells. In Fig. 6A, note that injection of a 20-pA depolarizing current from -10-pA holding current evoked cell activity consisting of a short barrage of action potentials followed by a plateau depolarization and resulted in a barrage of amperometric events. This type of cell activity is typical for single rat beta-cells. In these experiments with single cells (n = 3), we were not successful in obtaining either (i) consistent single APs in response to very brief current injections, probably due to the paucity of expression of sodium channels in the rat beta-cell (12, 13) or (ii) consistent release in response to plateau depolarizations, probably due to exhaustion of the previously loaded 5-HT. However, the feasibility for eventual success with such experiments is demonstrated by the voltage clamp experiment in Fig. 6B. Note here that brief (50-ms) depolarizations to +30 mV, applied at a frequency of 1 Hz, produced detectable release of at least one quantum, each of which began either during or immediately after the depolarization (n = 5).


Figure 6: Quantal secretion induced by prolonged electrical activity and brief depolarizations nearly simulating single action potentials. Panel A shows that prolonged (10-s) injection of depolarizing current (-10 pA) results in (i) an initial barrage of APs followed by plateau depolarization (see V(m) trace) and (ii) a concurrent barrage of amperometric spike events (see I trace). The inset shows initial electrical activity at an expanded time scale. Panel B shows that brief (50-ms duration) square pulses of depolarization to +30 mV, repeated at 1 Hz, result in individual ASs. The inset shows that ASs occur during, as well as some ms after, the depolarization. As these recordings were made with a K-IS pipette, membrane currents consist of a small initial inward current, in this case probably a combination of I and I, followed by a larger outward I.



Amperometric Detection of Stimulus-secretion Coupling in beta-Cells

In several small diameter secretory cells, it has been demonstrated that current wave forms (``action currents''), associated with action potentials in the rest of the cell membrane, which is not voltage-clamped, may be recorded extracellularly (i.e. by capacitative coupling) from cell-attached membrane patches(14, 15) . In beta-cells subjected to cell-attached patch recording, exposure to concentrations of glucose or tolbutamide sufficient to close most of the K (ATP) channels, often results in the onset of vigorous action current activity(7, 15, 16, 17) . Fig. 7presents data obtained with combined application of cell-attached patch electrophysiology and amperometry to further examine, at the level of the single cell, the time course of events in the cascade of secretogogue-induced stimulus-secretion coupling. In this figure, a cell-attached patch was formed on a single cell, within a cluster of islet cells exposed to a substimulatory concentration of glucose. The amperometry electrode was positioned on the border of that cell and an adjacent one. The patch clamp current trace (I) shows that a puff of PSS containing 200 µM tolbutamide resulted in (i) the rapid onset of closure of single inwardly directed channel currents (left inset), typical of ATP-sensitive, tolbutamide-blockable K channels well characterized in these cells(7, 15, 16, 17, 18) , and (ii) the closely following onset of biphasic action currents of 3 Hz (right inset). The amperometric current trace (I) shows the onset of a barrage of broad ASs coincident with the onset of action currents. (In past experiments, we have shown that reducing extracellular [Ca] from 2 to 0.1 mM abolishes these action currents, suggesting that they are initiated by the opening of voltage-dependent Ca currents). (^6)This experiment, typical of a set of four, confirms, in real time, the postulated cascade of stimulus-secretion coupling in beta-cells, namely, closure of K (ATP) channels results in AP generation followed by granule exocytosis.


Figure 7: Cascade of events in stimulus-secretion coupling monitored by combined cell-attached patch recording and amperometry. A single cell, within a small cluster of islet cells bathed in a PSS containing 3 mM glucose, was patched in the cell-attached mode with a pipette containing K-IS and held at 0 mV. A CFE touched another region of the cell surface. Note, in the trace marked I, that application by puffer pipette of a PSS containing 200 µM tolbutamide resulted in rapid closure of ATP-sensitive K channels, identified by their typical gating (burst of short openings) and characteristic amplitude (5 pA amplitude at pipette holding potential 0 mV) (see left bottom inset), followed by the appearance of biphasic action currents (see right bottom inset). The onset of amperometric spikes (see I trace) coincided with the train of electrical activity. The slow time courses of individual AS events seen here, in contrast with the more rapid events in previous figures, was typical of recordings from cells within clusters. This phenomenon reflected slower diffusion of 5-HT to the sensor electrode, perhaps because significant granule release occurs at regions of cell-cell contact. As was the case with more rapid AS events, slower events were no longer evident when the holding potential of the CFE was decreased to +100 mV (data not shown), suggesting that they are produced by oxidation of a substance with a threshold of detection between +100 and +680 mV. Since rodent beta-cells in clusters are often electrical coupled(41) , some of the action potentials in the train may have been initiated in cells other than the one actually patched.




DISCUSSION

We have combined electrochemical amperometry with patch clamp electrophysiology to examine, in real time, quantal secretion of 5-HT from rat beta-cells during secretogogue-induced electrical activity, as well as during imposed cell depolarization. The justification for this approach is that pancreatic beta-cells from a variety of species, selectively take up 5-HT out of proportion to other islet cells, sequester 5-HT into granules, and then secrete 5-HT along with insulin when exposed to insulin secretogogues(19, 20, 21, 22) . Single cell secretion of 5-HT by beta-cells has been reported, in tandem, with rises in cytosolic Ca under conditions where stimulus-secretion coupling is maximized(6) . Our application of 5-HT amperometry has allowed us to examine aspects of the time course of exocytosis of a single quantum as well as the rapid (millisecond range) temporal coupling of depolarization to secretion. The advantages of this very rapid and sensitive single cell approach to the study of depolarization-secretion coupling over prior attempts, including combined perifusion and electrophysiology and membrane capacitance tracking, as well as some intrinsic limitations of this approach are discussed.

5-HT Amperometry as an Approach to Investigating Quantal Secretion in Rat Pancreatic beta-Cells

In our initial experiments with amperometry of 5-HT preloaded islet cells (depicted in Fig. 1and Fig. 2), we found that either of two insulin secretogogues known to depolarize beta-cells result, after a short latency, in the appearance of a barrage of pulse-like electrochemical signals. The average charge transfer represented by the signal signifies that up to hundreds of thousands of molecules are oxidized in each unit of release (see below). The threshold oxidation potential of the release substance (>+100 mV) is consistent with 5-HT being a principal species released. Furthermore, on lysis by saponin, similarly preloaded islet cells released material whose electrochemical (voltametric) profile was very similar to 5-HT (6) . Our choice of amperometry to detect 5-HT, a co-secretion or false transmitter, rather than insulin, the chief secretory substance in insulin granules, was based on several factors. The first is the relative ease of fabrication of uncoated CFEs used to detect 5-HT as compared with the ruthenium dimer/oxide-precoated CFEs needed to detect insulin. The second is our experience with the higher time resolution of quantal signals and with the stability and sensitivity of the uncoated CFEs compared with the apparent lability of the precoated CFEs, perhaps due to their ability to catalyze electro-oxidation of nontransmitter substances, such as buffers, abundant in the media.

There are several reasons why the signals we recorded are likely to originate, in large part, from exocytosis of insulin granules from beta-cells. First, our choice of the largest single cells visible for study (>10 µm in diameter) preselects with >80-90% probability for beta-cells as previously demonstrated by cell sorting(23) . This is now independently confirmed here; when so tested, most of our pre-selected cells responded to tolbutamide, a specific beta-cell secretogogue. Second, as noted above, beta-cells, and insulin granules in particular, selectively take up 5-HT(19, 20, 21) . Third, although smaller, -aminobutyric acid-containing granules, roughly the size of synaptic vesicles, are present in beta-cells, there is no evidence that these vesicles undergo regulated exocytosis(24) . In addition, the molecular content of the quantal event we have measured here is several times larger than that of a catecholamine-containing synaptic vesicle (11) , as might be expected for a granule with >125-fold greater volume than the synaptic vesicle. Fourth, the time courses of amperometrically measured quantized release of insulin from single beta-cells stimulated by tolbutamide and K is similar to those observed here for release of 5-HT when differences in agonist concentration are taken into account(5) . Fifth, in later experiments, we were able to identify beta-cells electrophysiologically by their display, at high density, of distinctive ATP-sensitive K channels. Sixth, all amperometric signals were evoked under conditions under which insulin granule release was expected.

The use of our newly designed polypropylene insulated carbon fiber electrode (ProCFE) facilitated combination of high resolution electrophysiological and electrochemical recordings. In comparison with previously described glass/epoxy-insulated carbon fiber electrodes (geCFEs) (25, 26) and peCFEs(2, 4) , the newly designed ProCFE combines several critical features. These are (i) the mechanical stability, particularly at physiological temperatures, as compared with the widely used geCFE; (ii) the relatively lower noise and smaller tip dimension that previously promoted the use of a peCFE in combined electrophysiological/electrochemical recording; and (iii) the simple structure and manufacturing process. While the ProCFE consists of only a carbon fiber and polypropylene insulation, both the peCFEs and geCFEs require at least three kinds of material.

The Unitary Quantal Signals

Features of the individual 5-HT signals may offer some insight into the nature of exocytotic release of 5-HT from beta-cells. The spike-like nature of individual amperometric signals, namely rapid time to peak and brief half-height duration, is similar to that of amperometric events recorded by similar techniques from chromaffin cells and widely accepted as exocytotic in origin(1, 2) . This is so despite of the widely different molecular contents of the amperometric events; the average charge of individual ASs from rat beta-cells, 56 femtocoulombs, corresponding to 1.75 times 10^5 5-HT molecules, is 3.5 times larger than that from the developing nerve terminal (11) but 20 times smaller than that from chromaffin cells. (^7)Furthermore, with our improved sensitivity recording, small, brief, but discrete signals can be seen at the rising edge of even widely isolated, low frequency events; these are reminiscent of ``foot'' or prefusion signals seen with chromaffin cell events(2, 27) . These comparisons suggest that the kinetics of exocytosis of the false transmitter 5-HT from beta-cells may be similar to the release of the physiological transmitter epinephrine from similarly sized chromaffin granules. Closer correlation of the time courses of exocytotic release of insulin and 5-HT from beta-cells will be needed, especially since evidence from electron microscopy suggests that insulin may be released as a crystalline granule that subsequently must decondense.

Combined Electrophysiological/Electrochemical Studies of Depolarization-secretion and Agonist-secretion Coupling in Rat beta-Cells

These experiments revealed that quantal release of 5-HT was rapidly activated by cell depolarization to voltages that evoke measurable Ca currents in a given single cell. Release was graded with Ca entry; depolarizations to voltages that evoke larger Ca currents produce more frequent AS events during the course of the depolarization. Brief depolarizations evoked single amperometric events with variable latency, ranging from 5 ms after the start of a 50-ms depolarization to hundreds of ms after its cessation (see Fig. 6B). Prolonged depolarizations, either in the voltage or current clamp mode, often resulted in discharge throughout, although release frequency appeared to decline with time. Furthermore, the exocytotic nature of release was supported by correlation of the number of release events, recorded during cell depolarization, with the increase in membrane capacitance measured shortly (usually within 1-2 s) thereafter. These features were previously seen with combined amperometric and electrophysiological studies of adrenal chromaffin cells(1, 2) , another excitable endocrine cell. Taken together, these results provide further evidence that these endocrine cells display voltage-activated, Ca entry-dependent secretion resembling that seen in neurons. However, the longer latencies of release after Ca entry suggest that, in these endocrine cells, part of the action of Ca may be more distant from its entry site or more delayed than in neurons(2, 4, 28) .

Using single rat beta-cells recorded from in the perforated patch mode, we encountered some difficulty in (i) triggering single APs with brief depolarizing current pulses and (ii) evoking sustained electrical activity with a secretogogue such as tolbutamide. Many cells developed wobbly, plateau-like depolarizations (see Fig. 6). Other cells with more discrete APs were less than optimal for study because they failed to secrete reliably. However, better results were obtained recording from cells in clusters, particularly when cell-attached patch recording was used. In these experiments, it was possible to view aspects of an entire cascade of events involved in the induction of secretion by tolbutamide. These include rapid closure of ATP-sensitive K channels critical to the maintenance of the resting membrane potential, subsequent onset of electrical activity (biphasic action currents), and, coincident with the onset of electrical activity, quantized release of 5-HT. This approach should be very useful in determining the relative contribution of different steps in the stimulus-secretion cascade to the heterogeneity of agonist responsiveness seen in single cells.

Comparison with Other Approaches to Assay Stimulus-secretion Coupling: Limitations and Perspective

To be sure, the combination of electrophysiology and amperometry stands in a long tradition of approaches to relate electrical activity and secretion in beta-cells either by simultaneous or sequential monitoring of events. Earlier approaches have included (i) single islet perifusion (followed by radioimmunoassay of the perifusate for insulin) combined with simultaneous electrical recording from a single cell within the islet (29) and (ii) single cell immunochemical assay of insulin release (by reverse hemolytic plaque assay) followed by patch clamp recording from the identified cell(12) . At best, these assays have permitted resolution of insulin secretion over many seconds to minutes. More recently, membrane capacitance tracking has offered a more real time single cell assay of exocytosis. Using this approach, it has been possible in single cells (i) to quantitate the dependence of release on voltage-activated entry of Ca and other divalent cations(30, 31, 32, 33) , as well as bulk cytosolic concentrations of these ions (32, 33, 34) and (ii) to examine the roles of protein kinase and phosphatase activation in modulating Ca-dependent release(35, 36, 37) . However, major drawbacks of this approach include (i) poor resolution at the level of release of one to several granules, often requiring extended depolarization to reveal release; (ii) the requirement that the cell be voltage-clamped during the capacitance measurement, a condition that precludes real time monitoring of electrical activity induced release under physiological conditions; and (iii) uncertainty that chemical release is actually occurring. Our evidence suggests that the combination of amperometry and electrophysiology eliminates all three of the aforementioned drawbacks of capacitance tracking. However, the need for close apposition of the electrode and the release site imposes the drawback that amperometry only captures a fraction of release events. Where possible, combination of amperometry and capacitance tracking might provide an ideal approach.

A disappointing feature of the application of the highly sensitive 5-HT amperometric assay to rat beta-cells is its lack of robustness in measuring secretion. This often precluded extended or detailed quantitative studies. To be sure, as with all single cell assays, only a fraction (leq50%) of beta-cells secrete in response to secretogogues or direct stimulation. Of more concern is the rapidity with which secretion in most cells declines to barely detectable levels during even short, repetitive bouts of depolarization in the presence of cAMP-enhancing agents thought to increase the secretion-ready granule pool. While the loading of granules appears to be dependent on the bath concentration of 5-HT, it is not clear what factors contribute to 5-HT retention or redistribution after loading. At this time, it is uncertain what percentage of granules actually load with 5-HT and whether these represent a specific fraction. Electron microscopic autoradiography of random sections of ^3H-5-HT-loaded beta-cells show radioactive vesicles dispersed within much of the vesicle pool(13) , but evidence from serial reconstruction is lacking. This feature of limited loading might be overcome with improved loading techniques and/or extension of current approaches to islets of other species. For example, in early experiments, canine islet cells display quantal events with 5 times the molecular content of those from rat. Although their amplitude slowly declines with time, these events remain detectable over many minutes, especially when short periods of rest are interspersed between bouts of electrical activity(42) .


FOOTNOTES

*
This work was supported by grants from the National Institutes of Health (DK37380) and the American Heart Association (to S. M.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
Supported by a fellowship from the McDonnell Center for Cellular Neurobiology at Washington University. To whom correspondence should be addressed: Dept. of Physiology, Loyola University Medical Center, Maywood, IL 60153.

Established Investigator of the American Heart Association.

(^1)
The abbreviations used are: 5-HT, 5-hydroxytryptamine; AP, action potential; AS, amperometric spike; [Ca], external Ca concentration; CFE, carbon fiber electrode; C(m), membrane capacitance; I, amperometric current; I, calcium current; I(m), membrane current; I, depolarizing current pulse; ProCFE, polypropylene-coated CFE; peCFE, polyethylene-insulated CFE; geCFE, glass/epoxy-insulated carbon fiber electrode; PSS, physiological saline solution; Q, charge transfer during an AS; V(m), membrane potential; F, farad(s); , ohm(s).

(^2)
Tolbutamide is an oral hypoglycemic sulfonylurea. In beta-cells, it specifically closes ATP-sensitive K channels and promotes cell depolarization and [Ca]-dependent insulin secretion(16, 17, 18) .

(^3)
The threshold potential for 5-HT oxidation is 300 mV(38) .

(^4)
While it has generally been assumed that there are two electro-oxidations/5-HT molecule(38) , a recent study suggests, at least in some cases, that four electro-oxidations/5-HT molecule may be occurring(39) .

(^5)
In our cells, there were no exogenous Ca buffers, such as Fura-2, to disturb mobility and alter cytosolic Ca levels.

(^6)
S. Misler, L. Falke, and K. D. Gillis, unpublished data.

(^7)
Based on a measured inner diameter of 322 nm(40) , we estimate the 5-HT concentration of an insulin granule to be 8.5-17 mM, depending the choice of estimate of the oxidation number for 5-HT, as compared with a catecholamine content of several hundred mM in a similarly sized chromaffin granule.


ACKNOWLEDGEMENTS

We thank J. Fink for cell preparation, Yan-Fang Hu for assistance in preparing the amperometric electrodes, and Dr. D. Barnett for comments on the manuscript. We also thank Dr. K. Kawagoe of Axon Instruments for noise measurements of ProCFEs.


REFERENCES

  1. Wightman, R. M., Jankowski, J. A., Kennedy, R. T., Kawagoe, K. T., Schroeder, T. J., Leszczyozyn, D. J., Near, J. A., Diliberto, E. J., Jr., and Viveros, O. H. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 10754-10758 [Abstract]
  2. Chow, R. H., Rüden, L. V., and Neher, E. (1992) Nature 356, 60-63 [CrossRef][Medline] [Order article via Infotrieve]
  3. Toledo, G. A., Fernandez-Chacon, Z. L., and Fernandez, J. M. (1993) Nature 363, 554-558 [CrossRef][Medline] [Order article via Infotrieve]
  4. Zhou, Z., and Misler, S. (1995) J. Biol. Chem. 270, 3498-3505 [Abstract/Free Full Text]
  5. Kennedy, R. T., Huang, L., Atkinson, M. A., and Dush, P. (1993) Anal. Chem. 65, 1882-1887 [Medline] [Order article via Infotrieve]
  6. Smith, P., Duchen, M., and Ashcroft, F. M. (1995) Pfluegers Arch. Eur. J. Physiol. 430, 808-818 [Medline] [Order article via Infotrieve]
  7. Misler, S., Falke, L. C., Gillis, K., and McDaniel, M. L. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 7119-7123 [Abstract]
  8. Hamill, O. P., Marty, A., Neher, E., Sakmann, B., and Sigworth, F. J. (1981) Pfluegers Arch. Eur. J. Physiol. 391, 85-100 [Medline] [Order article via Infotrieve]
  9. Zhou, Z., and Neher, E. (1993) J. Physiol. (London) 469, 245-273
  10. Herrington, J. and Bookman, R. (1993) Pulse Control Manual , University of Miami Press, Miami
  11. Zhou, Z., and Misler, S. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 6938-6942 [Abstract]
  12. Hiriart, M., and Matteson, D. R. (1988) J. Gen. Physiol. 91, 617-639 [Abstract]
  13. Pressel, D. M., and Misler, S. (1991) J. Membr. Biol. 124, 239-253 [Medline] [Order article via Infotrieve]
  14. Fenwick, E. M., Marty, A., and Neher, E. (1982) J. Physiol. 331, 577-597 [Abstract]
  15. Ashcroft, F. M., Harrison, D. E., and Ashcroft, S. J. H. (1984) Nature 312, 446-448 [Medline] [Order article via Infotrieve]
  16. Rorsman, P. and Trube, G. (1985) Pfluegers Arch. Eur. J. Physiol. 405, 305-309 [Medline] [Order article via Infotrieve]
  17. Trube, G., Rorsman, P., and Ohno-Shosaku, T. (1986) Pfluegers Arch. Eur. J. Physiol. 407, 493-499 [Medline] [Order article via Infotrieve]
  18. Gillis, K. D., Gee, W. M., Hammoud, A., McDaniel, M. L., Falke, L. C., and Misler, S. (1989) Am. J. Physiol. 257, C1119-C1127
  19. Ekholm, R., Ericson, L. E., and Lundquist, I. (1971) Diabetologia 7, 339-348 [Medline] [Order article via Infotrieve]
  20. Hellman, B., Lernmark, Å., Seblin, J., and Täljedal, I.-B. (1972) Biochem. Pharmacol. 21, 695-706 [Medline] [Order article via Infotrieve]
  21. Gylfe, E. (1978) J. Endocrinol. 78, 239-248 [Abstract]
  22. Gylfe, E. (1980) Acta Physiol. Scand. 109, 155-161 [Medline] [Order article via Infotrieve]
  23. Pipeleers, D. G., in't Veld, P. A., Van de Winkel, M., Maes, E., Schuit, F. C., and Gepts, W. (1985) Endocrinology 117, 806-816 [Abstract]
  24. Reetz, A., Solimena, M., Matteoli, M., Folli, F., Takei, K., and DeCamilli, P. (1991) EMBO J. 10, 1275-1284 [Abstract]
  25. Armstrong-James, M., and Millar, J. (1979) J. Neurosci. Meth. 1, 279-288 [CrossRef][Medline] [Order article via Infotrieve]
  26. Kawagoe, K. T., Zimmerman, J. B., and Wightman, R. M. (1993) J. Neurosci. Meth. 48, 225-240 [CrossRef][Medline] [Order article via Infotrieve]
  27. Zhou, Z., Misler, S., and Chow, R. H. (1995) Biophys. J. 68, A117
  28. Chow, R. H., Klingauf, J., and Neher, E. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 12765-12769 [Abstract/Free Full Text]
  29. Scott, A. M., Atwater, I., and Rojas, E. (1981) Diabetologia 21, 470-475 [Medline] [Order article via Infotrieve]
  30. Gillis, K. D., and Misler, S. (1992) Pfluegers Arch. Eur. J. Physiol. 420, 121-123 [Medline] [Order article via Infotrieve]
  31. Åmmälä, C., Eliasson, L., Bokvist, K., Larson, O., Ashcroft, F. M., and Rorsman, P. (1993) J. Physiol. (London) 472, 665-688
  32. Barnett, D. W., and Misler, S. (1995) Pfluegers Arch. Eur. J. Physiol. 430, 593-595
  33. Proks, P., and Ashcroft, F. M. (1995) J. Physiol. (London), in press
  34. Bokvist, K., Eliasson, L., Åmmälä, C., Renström, E., and Rorsman, P. (1995) EMBO J. 14, 50-57 [Abstract]
  35. Åmmälä, C., Ashcroft, F. M., and Rorsman, P. (1993) Nature 363, 356-358 [CrossRef][Medline] [Order article via Infotrieve]
  36. Gillis, K., and Misler, S. (1993) Pfluegers Arch. Eur. J. Physiol. 424, 195-197 [Medline] [Order article via Infotrieve]
  37. Åmmälä, C., Eliasson, L., Berggren, P.-O., Honkanen, R. E., Sjöholm, A., and Rorsman, P. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 4343-4347
  38. Stamford, J. A., Crespi, F., and Marsden, C. A. (1992) in Monitoring Neuronal Activity (Stamford, J. A., ed) pp. 113-145, ILP, Oxford
  39. Bruns, D., and Jahn, R. (1995) Nature 377, 62-65 [Medline] [Order article via Infotrieve]
  40. Dean, P. M. (1973) Diabetologia 9, 115-119 [Medline] [Order article via Infotrieve]
  41. Perez-Armendariz, M., Roy, C., Spray, D. C., and Bennett, M. V. (1991) Biophys. J. 59, 76-92 [Abstract]
  42. Zhou, Z., and Misler, S. (1995) Soc. Neurosci. Abstr. 21, 334

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