ABSTRACT
Two recently identified channel types in Lymnaea stagnalis heart muscle cells were shown to conduct Na+ in the absence of extracellular Ca2+. They did not appear to be ‘voltage-gated’ as they were not activated by voltage. Also, they remained active over a wide range of membrane potentials. However, they were weakly ‘voltage-sensitive’ as their activity usually tended to increase with depolarization. The weak voltage-sensitivity and similarity to other non-voltage-gated Ca2+ channels suggested that one or both of these channels may be receptor-operated Ca2+ channels.
One of the two channels had a slope conductance of 15 pS. The other appeared to have at least two subconductance states with slope conductances of 50 and 72 pS. Both these conductance states had very similar open dwell-time constants and identical reversal potentials. The open dwell-time constants of both conductance states were not affected by voltage, suggesting that the channels’ weak voltage-sensitivity was mediated by one of the closed states.
With divalent cations in the patch pipette, non-voltage-gated Ba2+ and Ca2+ currents were also detected. The Ba2+ conductance (12 pS) was similar to the Ca2+ conductance (11 pS).
INTRODUCTION
Bolton (1979) and Weiss (1981) discussed the possibility that some calcium channels in cell membranes are not gated by a change in membrane voltage, but depend on the presence of an appropriate agonist for the channel to open, i.e. that they form a class of receptor-operated channels. Only a few examples of such single-ion channels have been discovered so far to support this possibility. These include the calcium channel in human lymphocytes which is activated by phytohaemagglutinin (Kuno et al. 1986); the calcium channel in rabbit smooth muscle activated by ATP (Benham and Tsien, 1987); the thrombin-activated calcium channel in human platelet membranes (Zschauer et al. 1988); and the inositol-l,4,5-trisphosphate-activated calcium channel in sarcoplasmic reticulum vesicles from canine aortic smooth muscle (Ehrlich and Watras, 1988). A non-voltage-gated channel permeable to calcium and barium has also been reported in Aplysia neurone membrane fragments (Coyne et al. 1987). Previous experiments on Lymnaea heart ventricle muscle cells indicate that receptor-operated calcium channels might also exist in these cells (Gardner and Brezden, 1984).
Once appropriate dissociation conditions had been discovered for isolating the Lymnaea heart cells (Gardner and Brezden, 1990), we were able to reveal a suite of cationic channels that conduct sodium ions when extracellular (i.e. patch electrode) calcium ions were kept below 10 μmol 1−1 (Gardner and Brezden, 1990). Only one of these, a rarely observed low-conductance channel, showed voltage-dependent activation (VG channel). In contrast, a novel stretch-activated Na+-conducting channel (SAN channel) was also described. The SAN channel is different from the well-characterized, stretch-activated potassium-conducting (SAK) channel (Brezden et al. 1986; Sigurdson et al. 1987).
Two other channels, distinguished by different conductances, were labelled ‘small-conductance’ (SG) and ‘large-conductance’ (LG) channels. Unlike the VG channel, SG and LG channels were not activated by voltage steps (i.e. they were not voltage-gated), they were insensitive to stretch, were not activated by the dihydropyridine (DHP) agonist Bay K 8644, and were blocked by 10 μmol 1−1 Ca2+ or Cd2+, or by 1.0 mmol I−1 Co2+. These properties of SG and LG channels make them distinct from the L-type, voltage-gated, DHP-sensitive Ca2+ channel summarized by Tsien et al. (1988). Rather, SG and LG channels appear more similar to receptor-operated Ca2+ channels (Kuno et al. 1986; Benham and Tsien, 1987; Zschauer et al. 1988; Ehrlich and Watras, 1988). Non-voltage-gated Ba2+ and Ca2+ currents were also detected in Lymnaea ventricle cells (Gardner and Brezden, 1990).
We have now obtained sufficient single-channel current data to enable a more detailed description of the kinetic properties of these LG and SG channels and these divalent cation currents in Lymnaea heart muscle cells. We discuss the possibility that at least one of these channel currents may be due to Na+ passing through a receptor-operated calcium channel.
MATERIALS AND METHODS
The procedures for isolating and patch-clamping Lymnaea heart ventricle cells have been described in detail elsewhere (Brezden et al. 1986; Gardner and Brezden, 1990). Briefly, cells were dissociated by enzymatic dispersion (trypsin and collagenase) in 0.5 mmol 1−1 Ca2+ Leibovitz’s medium and plated onto cover glasses. Micropipettes were pulled from thick-walled Corning 7052 (Kovar) glass. The tips were coated with Sylgard 184 elastomer (Dow Coming) and were heavily fire-polished. Channel currents were amplified with a List EPC-7 patch-clamp amplifier (Medical Systems Corp.). The data were recorded at 10kHz on video cassette tape using a digital recorder (Instrutech VR-10). Data were filtered at 1–4 kHz (front panel setting) with four-pole Bessel filters, and subsequently processed and analysed with the pCLAMP program (version 4.5, Axon Instruments, Inc.). The analysis, fitting procedures and statistical tests employed are described by Sigurdson et al. (1987).
To ensure a very low Ca2+ concentration in the pipette, 1 mmol 1−1 EGTA was added to nominally zero-Ca2+ saline. Using the dissociation constant of Owen (1976) and the maximum residual Ca2+ content of the NaCl, the calculated Ca2+ concentration in the ‘Ca2+-free’ saline was 3.2 nmol 1−1. The pipette and bath saline compositions are given in Table 1. To avoid entry of bath saline into the pipette tip, positive pressure was maintained in the pipette until the tip came in contact with the cell membrane. Unless otherwise stated all values are presented as mean±s.d.
RESULTS
The single-channel currents described below, whether carried by Na+, Ca2+ or Ba2+, were labile. Channel activity either stopped abruptly, or tapered off at various rates, disappearing within a few seconds to a few minutes of seal formation. In most cases channel activity lasted for only a few seconds after seal formation; only on rare occasions did channel activity persist for more than 10 min. When activity ceased, the channels could never be re-activated by depolarizing voltage steps (see also Gardner and Brezden, 1990).
F Estimates of the potential difference across the membrane patch (Vm) were based on the data of Brezden et al. (1986), who found the resting potential of isolated Lymnaea stagnalis heart ventricle cells to be −60mV. Thus Vm = (−60 – Vp) mV, where Vp is the pipette potential. All data are from cell-attached patches, and voltages are given as Vm.
The small-conductance channel
The small-conductance (SG) channel (Fig. 1A) was detected in only about 10 % of the patches. It was usually characterized by infrequent bursts of activity separated by long intervals of inactivity, but occasionally remained very active for several minutes. The SG currents, which were − 1.0±0.2pA in amplitude at a Vm of −60 mV (Fig. 2), were detected at membrane potentials between −100 and −40 mV. However, because of their small size, they could not be accurately measured at membrane potentials more positive than −40 mV, where the signal-to-noise ratio was poor. The slope conductance was 15 pS, and the reversal potential, determined by extrapolating the current/voltage curve (assuming linearity), was about −10 mV (Fig. 3). This channel usually became more active at depolarized potentials. In one patch, for example, the probability of a channel being open (Po) was 0.18 at a membrane potential of −60 mV and 0.25 at −50 mV.
The open dwell-time distribution was best fitted by one exponential term, suggesting that this channel has a single open state. The open dwell-time constant, τo, was 1.0±0.05ms (±S.E.) at a membrane potential of−−60mV (Fig. 4). It was insensitive to voltage, ranging in a random fashion from 0.9 to 1.2 ms at membrane potentials between −40 and −100mV (data not shown, N=5 patches). -
Closed dwell-times, measured only within clearly defined bursts where no superimposed openings were observed, were best fitted by two exponential terms with time constants of 0.3±0.02ms (±S.E.) and 1.8±0.2ms (±S.E.) (Vm= −60mV) (Fig. 5). As the SG bursts were infrequent, the closed times between bursts were not included in the analysis because too few data points were available.
The large-conductance channel
The large-conductance (LG) channel (Fig. IB) was the most readily detected. It was also more persistent than the SG channel, occasionally remaining active for many minutes. LG channel currents were detected at membrane potentials between −110 and −40 mV. Events having different current amplitudes, but indistinguishable kinetics, were often observed. The ratio of the smaller to the larger amplitude at Vm = −60 mV was always about 2:3. In a representative patch, for example, the mean amplitudes were −2.3±0.3pA and −3.2±0.2pA (Fig. 6).
The open dwell-times for events of both amplitudes at Vm= −60 mV were best fitted by the sum of two exponential terms. The faster time constant, τo1, ranged from 0.2 to 0.6 ms for events of both amplitudes. The slower time constant, τo2, ranged from 1.4 to 2.8 ms for the smaller-amplitude events and 1.6 to 2.6 ms for the larger-amplitude events (N=7 patches). The combined open dwell-time data from events of both amplitudes at Vm = −60mV gave τo1 = 0.5±0.04ms (±S.E.) and τO2 = 1.8±0.6ms (±S.E.) (Fig. 7).
Direct transitions from one amplitude to the other suggest that these events reflect different subconductance states of the same channel (Fig. 8). These transitions could not be attributed to the closings of a superimposed, smaller-amplitude channel because discrete, unitary events with the required amplitude of about − 1pA were absent from the patches where such transitions were observed. The slope conductance of the higher conductance state was 72pS, and for the lower state 50 pS (Fig. 9). The extrapolated reversal potentials for both sub conductances were nearly identical at about −20 mV. Brief (1–5 ms), discrete events with a larger amplitude of −5 to −6pA at Vm = −60mV were often observed (not shown). Whether these events represented a third subconductance state of the LG channel or whether they belonged to a different channel altogether could not be determined.
Channel openings usually appeared in closely spaced bursts at membrane potentials more positive than about −70 mV. Brief, single openings became more common at hyperpolarized potentials. Excluding bursts with superimposed openings from analysis, closed dwell-time data from seven patches =(Vm =−60 mV), where at least two LG channels were present (see Sigurdson et al. 1987), were best fitted by the sum of three exponential terms with closed dwell-time constants (τc) of τcl = 0.2±0.01ms (±S.E.), τC2 = 1.4±0.17ms (±S.E.) and τC3=10.5±1.7 ms (±S.E.) (Fig. 10). In data from seven patches τc1 ranged from 0.1 to 0.2 ms, τC2 ranged from 1.3 to 3.0 ms and τc3, which showed the largest variation from patch to patch, ranged from 6.8 to 52.6ms.
Like the SG channel, the LG channel activity also tended to increase with membrane depolarization, although there was no indication of voltage-induced gating. In one experiment, for example, the probability of the channel being open (Po) decreased from 0.12 to 0.05 when the membrane potential was changed from −40 to −100 mV. That this decrease was not due to the inevitable ‘run-down’ of the channel was confirmed by an increase in Po to 0.09 when the membrane potential was subsequently raised to −70 mV. Although the actual Po values varied considerably, the direct relationship between channel activity and membrane depolarization was observed in many patches.
Current reversals
Outward currents other than those of the SAK channel were generally not seen. Small outward currents of less than + lpA were occasionally observed at membrane potentials between 0 and +40 mV, but these could not be ascribed to any one channel type since there was always more than one channel present in the patch. At other times the membrane patch was either quiescent, or the activity was dominated by outward SAK channel currents, which became spontaneously active at more depolarized potentials.
Divalent cation currents
With 50 mmol 1−1 Ca2+ in the pipette, inward unitary currents were detected at membrane potentials between −80 and -30mV. These Ca2+-permeable (CaP) channel currents gave a mean current amplitude of − 1.1±0.1pA at Vm = −60mV. These events were very infrequent (Po<0.01), and disappeared within a short time of patch formation. Only short stretches of activity were detected, yielding sufficient data only for amplitude measurements. The slope conductance for this channel was about 11 pS. Extrapolation, assuming linearity, gave a reversal potential of about +30 mV for these currents (Fig. 12). There were insufficient data to examine the kinetics of this channel.
With 50 mmol 1−1 Ba2+ in the pipette, the mean unitary current amplitude was − 1.3±0.2pA at Vm= −60mV. These Ba2+-permeable (BaP) channel currents, which did not appear to be voltage-gated, were detected at membrane potentials between −80 and −20mV (Fig. 1D). The slope conductance was 12pS. Extrapolation of the current/voltage curve (assuming linearity) shows a reversal potential of about +55 mV (Fig. 13). The open dwell-times were best fitted by a single exponential function with time constants ranging from 1.3 to 1.6ms at Vm = −60 mV. Pooled data from six patches gave an open dwell-time constant of 4±0.1ms (±S.E.) (Fig. 14).
Like the SG channel currents, the Ba2+ events appeared in infrequent bursts of activity. Closed dwell-times were measured only within those bursts where no superimposed openings were observed. They were best fitted by two exponential terms with time constants of 0.3±0.02 ±S.E.) and 2.2±0.3ms (±S.E.) (Vm = −60 mV) (Fig. 15). The closed times between bursts were not included in the analysis because too few data points were available.
DISCUSSION
We have previously described several new types of channel currents in Lymnaea stagnalis heart ventricle cells (Gardner and Brezden, 1990). In this paper we examine the properties of the SG, LG and divalent ion currents in greater detail.
In the absence of patch pipette Ca2+, it is unlikely that either the SG or the LG current was due to Na+ passing through SAK channels because inward LG channel and SG channel Na+ currents, and outward SAK channel K+ currents, were frequently active simultaneously in the same patch (Gardner and Brezden, 1990). Also, the currents detected with 50mmol l−1 Ca2+ or 50mmol l−1 Ba2+ in the pipette could not be due to the influx of a different cation species since only Ca2+ or Ba2+ (as Cl− salts) and 5 mmol l−1 Hepes were present in the patch pipette. Neither could these currents, which were inward at Vm= −60 mV, have been due to an efflux of Cl− because the reversal potentials were much more positive than the Cl− equilibrium potential, which is close to the resting potential in these cells (Brezden and Gardner, 1984).
None of the channels described here appeared to be ‘voltage-gated’ since they were not activated by voltage steps. However, both the SG and LG channels were ‘voltage-sensitive’ in that Po often increased with membrane depolarization. The voltage-sensitivity of the LG channel, at least, would appear to be due to a reduction in one or more closed dwell-time constants, since the open dwell-time constants were not affected by a voltage change.
The BaP channel
The BaP channels in this study appear to be different from the Ba2+-permeable ‘HP’ channel recently found in Lymnaea stagnalis neurones (Yazejian and Byerly, 1989). Although both channels were weakly voltage-sensitive and neither was voltage-gated, the HP channel had a larger slope conductance (27 pS vs 12 pS for the BaP channel), and did not pass a detectable Na+ current in inside-out patches. However, as the HP channel was inactive in cell-attached patches (Yazejian and Byerly, 1989), it could not be determined whether the HP channels conducted Na+ in the intact cell. Whole-cell currents from Lymnaea neurones showed that 50 mmol l−1 Na+ produced only a slightly greater current than 60 mmol 1−1 Ba2+, but this Na+ current could not be attributed to ion flux through the HP channel.
The lack of HP channel activity in cell-attached patches invites comparison with our own inability to detect Ca2+ or Ba2+ currents in Lymnaea heart cells which had been dissociated and incubated in medium containing 3.5 mmol 1−1 Ca2+ (Gardner and Brezden, 1990). However, the neuronal HP channel appears to be activated in the cell-attached patch configuration by an increase in the intracellular Ca2+ concentration, whereas our evidence suggests that the BaP and CaP channels are activated by high intracellular [Ca2+] (Gardner and Brezden, 1990).
Comparison of the SG channel Na+ currents with BaP channel Ba2+ currents
Several characteristics were common to both the unitary SG channel Na+ currents and the BaP channel Ba2+ currents. The Ba2+ currents were similar in appearance to the SG Na+ currents (cf. Fig. 1A and ID). For both the SG and BaP channels, the open dwell-time distribution was described by a single exponential, while the distribution of the closed dwell-times within the bursts was described by two exponential terms. The activity of the BaP and SG channels was characterized by active stretches separated by relatively long intervals of low activity or inactivity (not evident in Fig. 1).
The reversal potential for the Na+ currents was considerably more negative than the reversal potential for the Ba2+ currents (−10mV vs +55mV). If SG and BaP are in fact the same channel, this suggests that the relative affinity of Na+ for the ion binding site(s) was lower than that of Ba2+. As a result, a counter-flux of K+ could more effectively shift the reversal potential for the Na+ current in the negative direction towards the K+ equilibrium potential (Hess et al. 1986). The data we have so far obtained for the CaP channel are also consistent with this view.
Also, ions with a lower affinity for the channel binding site(s) would be expected to have a higher throughput rate (higher conductance) because of a shorter dwell-time within the channel. If SG represented the same channel as BaP or CaP, it would be expected that a larger conductance would be seen with Na+ than with Ba2+ or Ca2+ as the charge carrier (Tsien et al. 1987). Our data are consistent with this expectation (15 pS for the SG currents, 11 pS for the CaP currents and 12 pS for the BaP currents).
LG channel subconductances
The LG channel is readily distinguished from the SG channel by its larger unitary current amplitude, and its very different kinetics (cf. Fig. 1A and Fig. 1B). Our evidence suggests that the LG channel may be able to assume at least two subconductance states, whereas the SG, BaP and CaP channels exhibited only a single amplitude level at any given membrane potential. Subconductance states have been described for L-type Ca2+ channels in vertebrate muscle cells (Pietrobon et al. 1988), and in reconstituted Ca2+-and Ba2+-permeable, nonvoltage-gated channels from Aplysia neurones (Coyne et al. 1987).
In several respects, the LG channel resembles the Ca2+-and Ba2+-permeable channel in Aplysia neurones (Coyne et al. 1987). Neither channel was voltage gated and both apparently can assume subconductance states. The open dwell-times of the two smaller subconductances of the Aplysia channel and the two subconductances of the Lymnaea LG channel were described by the sum of two exponential terms. In contrast, the Aplysia channel closed dwell-times are described by the sum of two exponential terms, whereas the Lymnaea LG channel closed dwell-times are best fitted by the sum of three exponential terms. The LG channel activity was often in the form of clearly defined bursts separated by relatively long interburst (‘between burst’) intervals. Therefore, it was possible to measure with reasonable accuracy the intra burst (‘within burst’) closed dwell-times from patches which contained more than one channel. The influence of another channel on intraburst closed dwell-time measurements could be virtually eliminated by excluding from analysis those bursts with superimposed channel openings. In contrast, measurements of interburst closed dwell-times, where consecutive bursts may belong to different channels, are much more uncertain (Sigurdson et al. 1987). Given these considerations, the two fastest closed dwell-time constants, τC1 and τc2, showed little variation from patch to patch. Therefore, they probably define the mean intraburst closed dwell-times where the measurement error is minimal. The slowest time constant, which showed the largest variation (ranging from 6.8 to 52.6ms), probably reflects the interburst closed dwell-time, where the largest measurement error would be expected. Considerable variation in the slowest time constant is also likely to result from the observed decfine of channel activity over time, which was not consistent from patch to patch.
The larger-amplitude events in the Aplysia channel were described by a single exponential term (Coyne et al. 1987). These latter events were very similar in appearance to the discrete large-amplitude events which we observed, but could not classify, in Lymnaea heart cell patches containing the LG channel. In contrast, Bay K 8644 had a marked effect on the Aplysia channel, whereas it had no discernible effect on the Lymnaea LG channel (Gardner and Brezden, 1990).
Channel identity
The following summarizes the evidence which suggests that the SG and LG channels may be Ca2+ channels: (1) the channels conduct Na+ only in the absence of Ca2+; (2) the channels are blocked by very low concentrations (10μmol l−1) of Ca2+ (Gardner and Brezden, 1990); (3) the channel currents are blocked by Co2+ and Cd2+, which are known Ca2+-entry blockers in these cells (Gardner and Brezden, 1990); (4) Ca2+ and Ba2+ currents can be detected, showing that Ca2+-permeable and Ba2+-permeable channels do exist in Lymnaea heart ventricle cells; (5) the reversal potentials of the SG and LG Na+ currents were much more negative than would be expected for a Na+-selective channel. This could be explained if Na+ was passing through a symmetrical Ca2+ channel which also allowed K+ to pass in the opposite direction (Reuter, 1983; Lee and Tsien, 1982). In this case, the inward Na+ current would be offset by an outward K+ current, since both ion types would permeate the channel.
Receptor-operated Ca2+ channels
The existence of receptor-operated channels was originally based primarily on indirect evidence (Bolton, 1979; Weiss, 1981). There are a few reports of nonvoltage-gated, Ca2+-conducting channels in molluscan cells (Chesnoy-Marchais, 1985; Coyne et al. 1987; Yazejian and Byerly, 1989). Although there is no strong evidence that these molluscan channels are receptor-operated, their weak voltage-sensitivity suggests that they may be either receptor-operated or gated via second messengers. Recently, however, several voltage-independent, Ca2+-conducting channels which are activated by a variety of agonist molecules have been reported for vertebrate cells. A Cd2+-sensitive, Ba2+-conducting channel in human T lymphocytes is activated by phytohaemagglutinin (Kuno et al. 1986). This channel is relatively non-selective for Ca2+. An ATP-activated, Ca2+-conducting channel has been found in rabbit smooth muscle cells (Benham and Tsien, 1987). These channels are insensitive to Cd2+ and also have a relatively low Ca2+/Na+ permeability ratio of 3:1. Thrombin-stimulated channels with a selectivity ratio for Ba2+/Na+ of 35:1 have been reported in human blood platelets (Zschauer et al. 1988). These channels have a Ba2+ slope conductance of 10pS, are blocked by Ni2+ and are insensitive to dihydropyridines.
As the SG, LG, BaP and CaP channels do not appear to be voltage-gated, it is possible that some or all of them are the receptor-operated (or second-messenger-operated) Ca2+ channels that we concluded must exist from our studies on the mode of action of the molluscicide Frescon (Gardner and Brezden, 1984). This hypothesis has since been strengthened by our recent discovery that channel currents with similar properties to SG, LG, BaP and CaP currents can be activated by FMRFamide and related substances (B. L. Brezden, P. R. Benjamin and D. R. Gardner, in preparation).
ACKNOWLEDGEMENTS
DRG thanks the Natural Sciences and Engineering Research Council of Canada for an operating grant (A-4290).