Abstract
The potassium M current was originally identified in sympathetic ganglion cells, and analogous currents have been reported in some central neurons and also in some neural cell lines. It has recently been suggested that the M channel in sympathetic neurons comprises a heteromultimer of KCNQ2 and KCNQ3 (Wang et al., 1998) but it is unclear whether all other M-like currents are generated by these channels. Here we report that the M-like current previously described in NG108–15 mouse neuroblastoma x rat glioma cells has two components, “fast” and “slow”, that may be differentiated kinetically and pharmacologically. We provide evidence from PCR analysis and expression studies to indicate that these two components are mediated by two distinct molecular species of K+ channel: the fast component resembles that in sympathetic ganglia and is probably carried byKCNQ2/3 channels, whereas the slow component appears to be carried by merg1a channels. Thus, the channels generating M-like currents in different cells may be heterogeneous in molecular composition.
The M current (IK(M)) is a low-threshold, slowly activating potassium current that exerts an inhibitory control over neuronal excitability; this inhibition can be relieved by neurotransmitters acting on G-protein-coupled receptors, leading to enhanced excitability and reduced spike-frequency adaptation (Brown, 1988; Marrion, 1997). The current was originally described in sympathetic neurons (Brown and Adams, 1980; Constanti and Brown, 1981), and analogous currents have subsequently been identified in a variety of other neuronal and non-neuronal cells. Because the precise kinetic and pharmacological properties of the current vary somewhat in different cell types, the name “M-like” is often applied to this current family.
Recently, evidence has been provided to indicate that the channels that generate the M current in rat sympathetic neurons are composed of a heteromeric assembly of KCNQ2 and KCNQ3 subunits (Wang et al., 1998; see also Yang et al., 1998). These are two homologs of the KCNQ1 (KvLQT1) channel, mutations of which are responsible for one form of the cardiac “long QT” syndrome (Yang et al., 1997). In contrast, KCNQ2 and KCNQ3are restricted to the nervous system, and mutations in these channels are associated with a form of infant epilepsy termed “benign familial neonatal convulsions” (Biervert et al., 1998; Charlier et al., 1998;Schroeder et al., 1998; Singh et al., 1998). However, it is not yet known whether all M-like channels are composed of these two subunits (or homologs thereof), or whether members of other K+ channel gene families might contribute to the generation of M-like currents.
In the present experiments, we have attempted to identify the molecular species of K+ channels that generate the M-like current (IK(M,ng)) in NG108–15 mouse neuroblastoma x rat glioma cells. These currents have been particularly well characterized (Higashida and Brown, 1986; Brown and Higashida, 1988a,b; Fukuda et al., 1988; Schafer et al., 1991; Robbins et al., 1992, 1993; Selyanko et al., 1995). Like the channels in sympathetic neurons, they are inhibited by transmitters acting on G-protein-linked receptors coupled to phospholipase C (e.g., bradykinin and M1 and M3 muscarinic receptors) (Higashida and Brown, 1986; Fukuda et al., 1988), with similar consequences for cell firing (Robbins et al., 1993). On the other hand, the kinetics of IK(M,ng)appear more complex than those of the ganglionic M current (Robbins et al., 1992), and the two currents differ in their sensitivities to 9-aminotetrahydroacridine (cf. Marsh et al., 1990; Robbins et al., 1992) and linopirdine (cf. Aiken et al., 1995; Lamas et al., 1997; Noda et al., 1998). It has previously been suggested thatShaker-type Kv1.2 channels, cloned from NG108–15 cells (Yokoyama et al., 1989), may contribute toIK(M,ng) (Morielli and Peralta, 1995). However, the insensitivity of IK(M,ng)to dendrotoxin (Selyanko et al., 1995) makes this unlikely. Instead, we provide evidence to indicate that two different types of K+ channel contribute to the M-like current in NG108–15 cells: the mouse ether-a-go-go-related gene (merg1a), also expressed in the brain (London et al., 1997), andKCNQ2/KCNQ3, the proposed substrate for the ganglionic current (Wang et al., 1998).
MATERIALS AND METHODS
Cell cultures. NG108–15 mouse neuroblastoma x rat glioma hybrid cells, subclone BM8 (PM1), transfected to express pig brain M1 muscarinic receptor (Fukuda et al., 1988), were cultured and differentiated as described previously (Robbins et al., 1992). Chinese hamster ovary (CHO) cells stably transfected with cDNA encoding human M1muscarinic receptors were maintained in culture as described inMullaney et al. (1993). Superior cervical ganglion neurons were prepared as described previously (Owen et al., 1990) from 6-week-old C57 mice and 14-d-old Sprague Dawley rats, and used after 1–2 d in culture. Recordings from all three types of cell were made at room temperature (20–22°C), under identical experimental conditions (solutions, pipettes, etc.).
Culture and transfection of CHO hm1 cells. CHO hm1 cells are CHO-K1 cells, previously transfected with the human M1 receptor (Mullaney et al., 1993). Cells were grown in 50 ml flasks at 37°C and 5% CO2. The culture medium was α-MEM supplemented with 10% fetal calf serum, 1%l-glutamine, and 1% penicillin/streptomycin. Cells were split twice weekly when confluent, plated in 35 mm dishes, and transfected 1–2 d after plating using “LipofectAmine Plus” (Life Technologies, Gaithersburg, MD) according to the manufacturer’s recommendations. Plasmids containing merg1a and CD8 cDNAs, both driven by cytomegalovirus promoter, were cotransfected in a ratio of 10:1. Cells for patch clamping were identified by adding CD8-binding Dynabeads (Dynal, Great Neck, NY) the day after transfection. For immunocytochemistry, a plasmid containing cDNA for jellyfish green fluorescent protein (GFP) was used as a marker for transfection.
Reverse transcription PCR. RNA was extracted from cell lines and superior cervical ganglia (SCG) using RNAzol B (Biogenesis Ltd.) and reverse-transcribed using oligo-dT and mouse murine leukemia virus reverse transcriptase (Promega, Madison, WI). The oligonucleotides used to amplify the erg gene family were:erg-s 5′ CCCYTTCAAGGCMGTGTGGG anderg-a 5′ CTGGTHAGRCTGCTGAAGGT. Primers were designed such that the amplified product spanned at least one intron to ensure amplification products were not derived from contaminating genomic DNA. The primers used for KCNQ PCR wereKCNQs 5′ACCTGGARGCTBCTGGCTC and KCNQa5′CCKCTYTTCTCAAAGTGCTTCTG. These primers were designed to amplify both KCNQ2 and KCNQ3 sequences. Cycling conditions were 95°C for 5 min and then 30 cycles of 95°C for 30 sec; 60°C for 1 min and 72°C for 1 min followed by a final step of 72°C for 10 min. Aliquots of the reaction mixture were visualized on a 2% (w/v) Metaphor agarose (FMC BioProducts, Rockland, ME). PCR products were cloned using the pGEM-T vector (Promega) and recombinant plasmids sequenced using Taq polymerase, fluoresceinated dye terminators and an Applied Biosystems 377 automated DNA sequencer.
Immunocytochemistry. This was performed using antibodies raised against synthetic peptides corresponding to the last 14 amino acids of the C-terminal fragment of merg1 (merg1-CT) and the first 17 amino acids of merg1b (merg1-NT), respectively. NG108–15 cells were seeded onto polyornithine-coated glass coverslips to allow immunocytochemistry. NG108–15 cells were washed in TBS (5.5 mm Tris, pH 7.4, and 137 mmNaCl) and fixed in acetone for 20 min at room temperature. The fixed cells were then treated with normal swine serum (1:10) in TBS for 30 min. Once excess serum was removed, the merg1-CT primary antibody was applied at 1:1000 dilution for 1 hr at room temperature. Different concentrations of the primary antibody were tested to optimize immunochemical labeling and minimize nonspecific staining of the tissue background. Bound antibodies were then detected using alkaline phosphatase-conjugated secondary antibodies (1:500; Dako, Carpinteria, CA), largely as described in Abogadie et al. (1997). Transfected mammalian CHO cells were briefly washed with PBS and fixed for 20–30 min in PBS containing 4% paraformaldehyde. Fixed cells were then rinsed with PBS, blocked for 10 min with BSA, and permeabilized with 0.1% Triton X-100 for 5 min. Incubation with the anti-merg1 antibody and labeling were carried out as described for the NG108–15 cells.
Perforated-patch whole-cell recording. Cells were bath-perfused with the solution of the following composition (in mm): 144 NaCl, 2.5 KCl, 2 CaCl2, 0.5 MgCl2, 5 HEPES, and 10 glucose, pH 7.4, with Tris base. Pipettes were filled with the “internal” solution containing 90 mm K acetate, 20 mm KCl, 40 HEPES, 3 MgCl2, 3 mm EGTA, and 1 mm CaCl2. The pH was adjusted to 7.4 with NaOH. Amphotericin B was used to perforate the patch (Rae et al., 1991). The series resistance was not compensated because the error introduced was reasonably small. Thus, with the electrodes used (2–3 MΩ), the series resistance was 6–8 MΩ, and most of the currents were <0.5 nA, so the voltage error would be <5 mV. As confirmation that the voltage error was small, no correlation was found between deactivation time constants and initial current amplitude.
Data acquisition and analysis. Data were acquired and analyzed using pClamp software (version 6.0.3). Currents were recorded using an Axopatch 200A (or 200) patch-clamp amplifier, filtered at 1 kHz, and digitized at 1–4 kHz. In current-clamp experiments, currents were injected, and membrane potential was recorded using an Axoclamp-2 amplifier. Activation curves were fitted by the Boltzmann equation:I/I(50) = 1/(1 + exp(V1/2 −V)/k), where I is current at the test potential (estimated from the amplitudes of exponentials backfitted to the beginning of the test step), I(50) is current at +50 mV, V1/2 is the membrane potential, V, at which I is equal to ½ I(50). Inhibition of the current was measured from the change in the amplitude of the deactivation tail recorded at −50 mV. Each tail was fitted by one or more exponentials, and the tail amplitude was taken as the sum of the amplitudes of all components contributing to it after backfitting them to the beginning of the hyperpolarizing pulse. In cells that had the erg-type component, backfitting was necessary to exclude not only the (relatively fast) capacity transient, but also the brief rising phase of the tail caused by the deinactivation of erg-type channels. To include the fast component (when present) in the fit, we had to position the fitting cursor earlier in the trace than was appropriate for the pure erg current. This tends to skew the τ values obtained for the erg components to larger values. This may explain the difference in slow τ values between the total and WAY 123,398-sensitive currents (Table1). Inhibition curves were fitted by the Hill equation: Y = Ymax * /( + IC50 ), where Ymax is the maximum inhibition,x is the blocker concentration, nH is the slope (Hill coefficient), and IC50 is the concentration corresponding to the half-maximal inhibition. Individual currents were measured and fitted using the Clampfit software, whereas the program “Origin” (version 5.0, Microcal Software) was used for fitting activation and inhibition curves and for creating the figures.
Drugs and chemicals. Linopirdine (DuP 996) was obtained from Research Biochemicals (Natick, MA). WAY 123,398 and azimilide were kindly provided by Wyeth-Ayerst Research (Princeton, NJ) and Dr. A. Busch (DG Cardiovascular, Frankfurt, Germany), respectively. All other drugs and chemicals were obtained from Sigma or BDH Chemicals (Poole, UK).
RESULTS
Fast and slow M-like (IK(M,ng)) currents in NG108–15 mouse neuroblastoma x rat glioma cells
We recorded M-like currents (IK(M,ng)) from 101 chemically differentiated NG108–15 cells using perforated-patch electrodes. Cells were carefully selected for their “neuron-like” appearance, i.e., large size and well-developed neuropil (Robbins et al., 1992). When studied with the conventional M-current voltage protocol, that is, by stepped hyperpolarization after predepolarization to approximately −20 mV (see Materials and Methods), currents showed characteristic M-like deactivation tails. However, the time course of these tail currents varied considerably from one cell to another. Figure1 illustrates two extreme examples of this variation. Thus, in Figure 1A, deactivation during a 6 sec hyperpolarizing step was very slow, with an apparent “time-constant” of ∼2 sec, whereas in Figure1B, deactivation was complete within 2 sec.
Because a number of tumor cells (including neuroblastoma cells) have been reported to express HERG-like currents with relatively slow rates of deactivation (Bianchi et al., 1998), we wondered whether these might contribute to the long deactivation tails. We tested this pharmacologically, using the HERGchannel-blocking drug WAY 123,398 (Spinelli et al., 1993; Faravelli et al., 1996). As shown in Figure 1A, 10 μm WAY 123,398 blocked most of the long deactivation, leaving a residual fast component which was then eliminated by the M channel-blocking drug linopirdine (Aiken et al., 1995; Lamas et al., 1997). In contrast, the fast-deactivating current in Figure 1B was strongly blocked by linopirdine, leaving a slower component that was blocked in turn by WAY 123,398. Thus, comparison of the linopirdine- and WAY-sensitive currents (Fig.1, inserts) showed that in fact each cell had two components to the deactivation currents, fast and slow, and that the overall time course of current deactivation was determined by their proportion. Furthermore, both components contributed to the sustained current recorded at −20 mV.
Because 10 μm WAY 123,398 produces a complete block oferg channels without affecting other K+ channels such as sympathetic neuron M channels (see below), we analyzed the fast and slow components of the deactivation tails in more detail by recording currents in the absence and presence of WAY 123,398. Figure 2exemplifies the results obtained in 86 of 101 cells so examined. Here, the control current recorded in the absence of WAY 123,398 (Fig.2A) showed three components, a fast component with a time constant of 76 msec, and a slower, biexponential component with time constants of 340 msec and 2.1 sec. WAY 123,398 (Fig.2B) eliminated the slower component, leaving only the fast component (τ, 75 msec), whereas the difference (WAY-sensitive) current (Fig. 2C) showed only the biexponential slow component (τ, 315 msec and 2.0 sec). Thus, the time constants of the residual current recorded after application of WAY 123,398 and of the subtracted (WAY-sensitive) current accurately reproduced the fast and slow components of the composite initial current. In this cell, the fast and slow components contributed 70 and 30%, respectively of the total tail current, and both contributed to the steady outward current at the holding potential as judged from the effect of WAY 123,398 on the holding current. On average, in the 86 cells expressing both currents, the fast- and slow-deactivating components contributed ∼33 and 67%, respectively, to the total tail current (Table 1). In the other 15 cells, the tail current showed only the slowly deactivating component and was fully suppressed by WAY 123,398.
mRNAs for merg1 and KCNQ2 andKCNQ3 in NG108–15 cells
The clearly distinguishable effects of linopirdine and WAY 123,398 on the tail currents illustrated in Figures 1 and 2 suggested that these might be composite currents, resulting from the deactivation of two different species of K+ channel: one composed of linopirdine-sensitive KCNQ2/3 subunits, or homologs thereof (Wang et al., 1998), and the other comprising a member (or members) of the erg family. We therefore sought evidence for the presence of transcripts of these channels by RT-PCR (see Materials and Methods). Transcripts for both erg andKCNQ2/3 were detected (Fig.3).
Sequence analysis of 10 independent clones from the erg PCR showed that each clone contained erg1 DNA sequence (data not shown), suggesting that these cells express predominantly, if not exclusively,merg1 transcript (London et al., 1997). TheKCNQ2/3 transcript contained mRNA for both KCNQ2and KCNQ3. It may be noted in Fig. 3 that these transcripts were also present in dissociated neurons from mouse and rat SCG (see also Shi et al., 1997; Wang et al., 1998).
Merg1 protein expression in chemically differentiated NG108–15 cells
The presence of mRNA transcripts does not necessarily correlate with translated protein products. We therefore tested for the expression of merg1a protein in NG108 cells by immunocytochemistry using a specific antibody raised against the C-terminal fragment of merg1 (merg1-CT; see Materials and Methods). As a control for specificity, the merg1-CT primary antibody was preincubated overnight with a 10-fold molar excess of the immunogenic peptide. Figure 4, A and B,compare merg1 immunolabeling in chemically differentiated and nondifferentiated NG108–15 cells, respectively. Strong labeling was observed in both cell bodies and neuropil of most large chemically differentiated NG108–15 cells of the type we normally selected for electrophysiological recording, whereas smaller cells with less well-developed processes showed weak or no immunoreactivity. No staining was observed in cells treated with preabsorbed antibody. Nondifferentiated cells, which normally expressed very smallIK(M,ng), showed moderate or no staining. Interestingly, no staining was observed in dissociated mouse SCG neurons (Fig. 4C), or over the underlying glial cell layer. This latter (negative) finding accords with the absence of any effect of WAY 123,398 on membrane currents recorded from these neurons (see below). Also, no immunostaining of differentiated NG108–15 cells was detected after exposure to an antibody raised against an N-terminal sequence unique to the short form of merg1 (merg1b), the expression of which is restricted to cardiac cells (London et al., 1997). This suggests that the protein tagged by the C-terminal antibody is the product of the long-form transcript merg1a (London et al., 1997; see also below).
Strong immunoreactivity for merg1-CT antibody was also detected in CHO cells transfected with merg1a cDNA. No staining was observed in untransfected cells, in cells transfected only with the GFP plasmid, or in cells treated with preabsorbed antibody (data not shown).
Slow IK(M,ng) is mimicked by merg1a current (Imerg1a) expressed in CHO cells
The above results suggested that the slow component of the M-like current in NG108–15 cells might well be carried by merg1a channels. We tested this further by expressing merg1a cDNA in mammalian CHO cells. Figure 5 illustrates the resultant membrane currents. Imerg1a was activated by membrane depolarization to equal or positive to −40 mV, but showed substantial inactivation during the (long) depolarizing command at potentials positive to 0 mV (Fig.5Aa). As a result, the “steady-state” current–voltage curve was “bell-shaped” (Fig. 5Ab). The time course of this composite activation (accompanied by inactivation) could be described by two exponentials, accelerating strongly with depolarization (Fig. 5Ac). When the cell was hyperpolarized after a depolarizing prepulse to +50 mV, there was a large transient enhancement of the current, caused by removal of channel inactivation, followed by a slower deactivation (Fig. 5Ba,b). Two deactivation components were detected that were strongly shortened by membrane hyperpolarization (Fig. 5Bc). The mean activation curve deduced from tail currents followed a Boltzmann equation withV1/2 = −5.9 ± 0.6 mV andk = 12.2 ± 0.5 mV (Fig. 5C). However, when individual curves were fitted, they showed a great variation inV1/2 (range, between −27 and 13 mV;n = 9) and small variation in k (range, between 6.9 and 10). These results accord well with previous observations on merg1a currents in oocytes (London et al., 1997).
We next compared the properties ofImerg1a deactivation more closely with those of the WAY-sensitive slow component ofIK(M,ng), using the “standard” M current protocol, that is, currents were preactivated by holding at the depolarized potential of 0 mV (−20 mV in the case ofIK(M,ng), to avoid contamination by other, primarily Ca2+-dependent, K+ currents) and then deactivated by 6 sec step commands to various negative potentials. As shown in Figure6, there was a close correspondence between the two. There were three main differences. First, deactivation of Imerg1a was preceded by a larger transient reactivation: this presumably reflected the greater steady-state inactivation of Imerg1aat 0 mV than that of slow IK(M,ng) at −20 mV. Second, the threshold for activation ofImerg1a was ∼10 mV more positive than that for slow IK(M,ng) (Fig.6Ab,Bb): the reason for this is not known but may simply relate to different cell types. Third, whereas both showed a biexponential deactivation, the time constants for the two components of Imerg1a deactivation measured at −50 mV were ∼40% of those for deactivation of the slowIK(M,ng) measured at the same potential (Table 1). The time constants showed a comparable voltage dependence (Fig. 6,compare Ac, Bc), so this difference may be explained by the different activation thresholds and/or the different size of the voltage step (in four CHO cells using a prepulse protocol, the first and the second slow deactivation τ values for Imerg1a were slower after a prepulse to −20 mV compared with a prepulse to 0 mV, by 41 and 57%, respectively).
For comparison, we also examined the properties of currents generated by the short “cardiac” isoform merg1b expressed in CHO cells (Imerg1b; n = 3; data not shown). Whereas the voltage dependence ofImerg1b activation and deactivation were very similar to that of the slowIK(M,ng) and ofImerg1a, both activation and deactivation of Imerg1b were several times faster (Table 1), as previously reported in oocytes by London et al. (1997) (see also Lees-Miller et al., 1997). Hence, and in accordance with the lack of antibody staining mentioned above and the absence of merg1b mRNA expression in the nervous system (London et al., 1997), it is unlikely that merg1b channels contribute to slowIK(M,ng).
Slow IK(M,ng) andImerg1a show similar pharmacology
We next compared the sensitivity of the slowly deactivating component of the NG108–15 currentIK(M,ng) with that of CHO-expressed merg1a currents to some blocking drugs. As shown in Figure7, both tail currents were blocked by the anti-arrhythmic drug WAY 123,398 with equal facility (IC50 values, 0.4 and 0.3 μm, respectively; Table2). They were also equally sensitive to another anti-arrhythmic drug, azimilide (IC50values, 6.4 and 6.5 μm, respectively; Table 2;Busch et al., 1998). Imerg1a was also inhibited by 9-aminotetrahydroacridine (THA; IC50value, 36 μm; Table 2), a compound that had previously proved unexpectedly potent in inhibiting the M-like current in NG108–15 cells (Robbins et al., 1992). In contrast, neither current was inhibited by the ganglionic M channel- and KCNQ2/3channel-blocking agent linopirdine at concentrations up to 30 μm [Noda et al. (1998) reported an IC50 of 36 μm against the NG108–15 current, but this was measured from the depression of the composite current, and the Hill slope was rather shallow, so probably reflected its primary action on the fast current component, see below]. Also, both currents were very insensitive to tetraethylammonium (TEA), with IC50 values of 17 and 24 mm (Table 2). Thus,Imerg1a provides a good match for the slowly deactivating component ofIK(M,ng), both kinetically and pharmacologically.
Fast IK(M,ng) is mimicked by the M current (IK(M)) in mouse sympathetic neurons
As noted above (Fig. 1), the fast component ofIK(M,ng) was readily suppressed by 10 μm linopirdine. Since linopirdine blocks M currents in sympathetic ganglia (Lamas et al., 1997; Wang et al., 1998), this suggested that fastIK(M,ng) might correspond to the “true” (ganglionic-type) M current. We assessed this by comparing fast WAY-insensitive IK(M,ng) with the M current recorded from dissociated mouse SCG neurons. (We usedmouse neurons because (1) the parent neuroblastoma to the NG108–15 hybrid cell line is derived from mouse neural crest; and (2) sequence analysis of the PCR products obtained with the KCNQprimers showed that NG108–15 cells expressed both the mouse KCNQ2 and the mouse KCNQ3. Because we have successfully used these primers to amplify the rat KCNQ2 and KCNQ3 genes, we conclude that NG108–15 cells express predominantly, if not exclusively, the mouse KCNQ genes.) Figure 8 shows families of fastIK(M,ng) (Aa) andIK(M) (Ba) activated by membrane depolarization to −20 mV and deactivated by 1 sec hyperpolarizations at −30 to −100 mV. The slow component ofIK(M,ng) was eliminated using 10 μm WAY 123,398, as shown in the box in Figure8. Fast IK(M,ng) andIK(M) had similar voltage dependences (Fig. 8A,B) to each other, and also to slowIK(M,ng) andImerg1a (compare Fig. 6). However, unlike slow IK(M,ng), deactivation tails of fast IK(M,ng) and mouseIK(M) were fitted with single exponential curves: these had time constants similar to each other but much shorter than those in the slowIK(M,ng) andImerg1a (Table 1).
Pharmacological comparison of fastIK(M,ng) and mouseIK(M)
Like fast IK(M,ng), mouseIK(M) was unaffected by 10 μm WAY 123,398.IK(M) recorded from 5 rat SCG neurons was also insensitive to this compound. Furthermore, both fastIK(M,ng) and mouseIK(M) were 1.5–2 orders of magnitude less sensitive to THA than were slowIK(M,ng) orImerg1a (IC50values, 1.5 and 1.3 mm; Table 2). This accords with the relative insensitivity of rat SCGIK(M) to THA reported previously (Marsh et al., 1990). Figure 9 shows the responses of fast IK(M,ng) and mouseIK(M) to linopirdine and TEA. Whereas both currents were considerably more sensitive than slowIK(M,ng) orImerg1a to linopirdine, the neuroblastoma–glioma current was clearly more sensitive than the mouse SCG current (IC50 values, 1.2 and 3.5 μm, respectively; Table 2). Likewise, fastIK(M,ng) was more readily blocked than the mouse IK(M) by TEA (see Discussion). Nevertheless, although not completely identical pharmacologically, fast IK(M,ng) and mouse SCG IK(M) are clearly similar and together show an obvious difference from slowIK(M,ng) andImerg1a.
Both fast and slow IK(M,ng), andImerg1a, are inhibited through activation of M1 muscarinic receptors
Activation of M1 muscarinic receptors inhibits both the total (composite) M-like current (IK(M,ng)) in NG108–15 cells (Fukuda et al., 1988; Robbins et al., 1991, 1993), and the M currentIK(M) in rat (Marrion et al., 1989;Bernheim et al., 1992) and mouse (Hamilton et al., 1997) sympathetic neurons. We therefore examined the effects of a muscarinic stimulant, oxotremorine-M (Oxo-M; 10 μm), on each component of IK(M,ng), as well asImerg1a, in M1muscarinic receptor-transformed NG108–15 and CHO cells. Figure10 shows that Oxo-M inhibited the slowIK(M,ng) (A) andImerg1a (B). Such inhibitions were observed in seven of eight NG108–15 cells (mean inhibition, 42.3 ± 13.8%) and six of six merg1a-expressing CHO cells (mean inhibition, 50.7 ± 10.8%). Inhibition of both slowIK(M,ng) andImerg1a was accompanied by a significant acceleration of their deactivation kinetics (Fig.11): on average, the two components in slow IK(M,ng) andImerg1a were shortened by 25.4 ± 10.0% and 34.6 ± 9.0% (n = 6) and 36.5 ± 4.8% and 27.8 ± 10.1% (n = 4), respectively.
Figure 12 shows examples of inhibitions of fast IK(M,ng) and mouseIK(M) by Oxo-M. Such inhibitions were observed in four of four NG108–15 cells (mean inhibition, 72.6 ± 13.8%; n = 4). As expected (Hamilton et al., 1997), similar inhibition was consistently observed in sympathetic neurons.
Fast and slow IK(M,ng) control firing in NG108–15 cells
The function of the M current is to act as a brake on repetitive firing. Thus, inhibition of the M current in sympathetic neurons, either by muscarinic agonists (Brown and Selyanko, 1985) or by an M channel-blocking agent (Wang et al., 1998), is associated with increased repetitive firing during depolarizing current injections. A similar effect has also been reported in M1-transformed NG108–15 cells after application of a muscarinic agonist (Robbins et al., 1993). However, in the latter case, it is not clear whether this results from inhibition of the fast or slow IK(M,ng), or both. We tested this by injecting long (7 sec) depolarizing currents into NG108–15 cells and then observing the effects of selectively inhibiting fast and slow IK(M,ng) with linopirdine and WAY 123,398, respectively. The depolarizing currents produced a short burst of repetitive firing in 20 of 22 NG108–15 cells tested and single action potentials in the remaining two cells. Figure13 shows that 30 μm linopirdine (which blocked the fast current completely and inhibited the slowIK(M,ng) by only 33%) produced a strong reduction in spike adaptation, whereas 10 μm WAY 123,398 had a much weaker effect. Neither linopirdine nor WAY 123,398 had any effect on spike repolarization.
DISCUSSION
The main point emerging from this work is that the M-like current in NG108–15 cells (IK(M,ng)) is a composite current generated by at least two channel types: a fast-deactivating set of channels similar (but not quite identical) to those carrying the M current in mouse sympathetic neurons and tentatively identified as KCNQ2/KCNQ3 (Wang et al., 1998), and a slower-deactivating current probably formed from merg1a (London et al., 1997). KCNQ2 and KCNQ3 are analogs of KCNQ1, which coassembles with KCNE(minK) subunits to give the cardiac currentIKs (the slow component of the cardiac “delayed rectifier”), and mutation of which causes one form of the cardiac long QT syndrome (Yang et al., 1997). KCNQ2and KCNQ3 have so far been detected only in brain and ganglia, and are implicated in a form of juvenile epilepsy (Biervert et al., 1998; Charlier et al., 1998; Schroeder et al., 1998; Singh et al., 1998; Yang et al., 1998). Merg1a is one isoform of the mouse homolog oferg, originally cloned from a rat brain hippocampal cDNA library (Warmke and Ganetzky, 1994); mRNA for erg is found mainly in heart and brain (London et al., 1997; Wymore et al., 1997). Mutations of the human homolog HERG give rise to a cardiac long QT syndrome (Curran et al., 1995; Sanguinetti et al., 1996), whereas mutations in Drosophila erg are responsible for the seizure phenotype associated with hyperactivity in the flight motor pathway (Titus et al., 1997; Wang et al., 1997). Thus, both these channel types have been implicated in the control of excitabilityin vivo. This is the first example of these two channels forming overlapping and functionally similar components of membrane current.
Our conclusion that two different channels are involved is based on: (1) the presence of mRNA transcripts and protein; (2) biophysical properties (voltage threshold and deactivation parameters); (3) sensitivity to potassium channel blockers; and (4) modulation of the channel by an agonist. Thus, we demonstrate the presence of mRNA and protein for merg1, and mRNA for KCNQ2 andKCNQ3, in NG108–15 cells. We show that the kinetics of merg1a heterologously expressed in mammalian cells correspond closely to those of the slow IK(M,ng). We also show that the two are equally sensitive to themerg-selective blocking agents WAY 123,398 and azimilide, and insensitive to the ganglionic M current and KCNQ2/3channel-blocking agent linopirdine. On the other hand, we find that the fast IK(M,ng) kinetically matches the mouse SCG IK(M), that these two are pharmacologically similar (although not quite identical), and that they can be distinguished from both slowIK(M,ng) andImerg1a by their greater sensitivity to linopirdine and insensitivity to WAY 123,398. We also show that both fast and slow components of IK(M,ng)are inhibited by stimulating M1 muscarinic acetylcholine receptors and that the nature of the inhibition of these two components matches that for inhibition of mouseIK(M) andImerg1a, respectively.
IK(M) in rat ganglion cells has been ascribed to current through channels composed of heteromultimeric assemblies of expressed KCNQ2 and KCNQ3 subunits (Wang et al., 1998). This may also be true forIK(M) in mouse ganglion cells and for the fast component of IK(M,ng) in NG108–15 cells, because we have found that both cell types show transcripts for these subunits. However, as yet, we cannot exclude a contribution from other, homologous, KCNQ subunits. Furthermore, fast IK(M,ng) was distinctly more sensitive to TEA and to linopirdine than was mouse ganglion IK(M), suggesting that the subunit composition of the presumed-KCNQ channels in these two cell types might differ.
The presence of functional merg1a channels in these cells is not, in itself, particularly surprising, because mRNA transcripts have been identified in a number of neuroblastoma-derived cells (including NG108–15) using probes to the human homolog HERG (Bianchi et al., 1998), and an “inwardly rectifying” current, retrospectively similar to an erg current, was reported in NG108–15 cells by Hu and Shi (1997) (see also Bianchi et al., 1998). However, in previous experiments, the properties of this current were mostly studied using solutions containing a raised K+ concentration, so that its relation to the M-like current was difficult to discern. It is clear from the present experiments (using normal external K+ concentrations) that the activation range of Imerg1a overlaps that of the true IK(M), but that deactivation ofImerg1a contributes a distinctive slow component to composite current deactivation; and furthermore, that the proportional contributions of Imerg1aand IK(M) to the total M-like current vary appreciably from cell to cell.
The merg1a and (presumed) KCNQ currents also overlap functionally. Thus, Chiesa et al. (1997) have provided evidence thaterg channels play a role in spike frequency adaptation in another neuroblastoma-derived cell line, not dissimilar to the role of ganglionic M channels (Jones and Adams, 1987; Brown, 1988). In the present experiments, it appeared that inhibition of the fast (M) channels had more effect on the response of NG108–15 cells to a sustained current injection than did inhibition of the slow (merg) channels (Fig. 13). However, the relative contribution of these two currents to spike frequency adaptation may depend on the nature of the testing pulse protocol, because merg currents activate and deactivate more slowly than KCNQ currents, and hence accumulate during repetitive depolarization (Schonherr et al., 1999).
The transduction mechanism for M1-mediated inhibition of KCNQ2/3 and merg1 is still unknown. Inhibition of Imerg1a and slowIK(M,ng) was accompanied by accelerated deactivation, which may indicate the involvement of protein kinase C (PKC); in HERG currents expressed inXenopus oocytes, similar acceleration produced by thyrotropin-releasing hormone receptor activation was mediated by PKC (Barros et al., 1998). This would accord with an earlier proposal regarding the mechanism of inhibition of the M-like current in NG108–15 cells by bradykinin (Higashida and Brown, 1986). Although M1 receptor activation in NG108–15 cells produces a strong elevation in intracellular [Ca2+] (Robbins et al., 1993), it is unlikely that Ca2+ could be a messenger for muscarinic inhibition of slowIK(M,ng) orImerg1a because, in CHO cells, the Ca2+ ionophore ionomycin (5 μm) produced an insignificant reduction inImerg1a (to 89.4 ± 9.7% of control; n = 3). As a control for the effectiveness of ionomycin in these cells, it caused a complete block of Kv1.2 channels expressed in CHO cells when recorded in perforated-patch or cell-attached configurations; direct application of 500 nm Ca2+ blocked Kv1.2 channels when recorded in the inside-out configuration (A. A. Selyanko and J. K. Hadley, unpublished observations).
Do products of erg genes contribute to M-like currents in other neurons? Transcripts for merg1 (London et al., 1997), and for the rat homologs erg1 and erg3 (Shi et al., 1997; Wymore et al., 1997) are present in mammalian brain. Furthermore, both expressed merg1a currents and the slow, presumed-merg1a component of the M-like current in NG108–15 cells were inhibited by stimulating M1muscarinic receptors, so they could contribute to muscarinic-inhibitable M-like currents previously recorded in central neurons. True, the presence of mRNA transcripts may not betoken the assembly of functional channels: thus, no appropriateerg-like component of membrane current could be recorded from mouse or rat sympathetic neurons, in spite of the presence of mRNAs (Shi et al., 1997; see also this paper), nor could we detect merg1 immunoreactivity. However, this may not be the case for other mammalian neurons. For example, the M-like current recorded from isolated rat cortical neurons has been reported to be an order of magnitude less sensitive to linopirdine than either the ganglionic or hippocampal cell current (Noda et al., 1998; cf. Aiken et al., 1995;Lamas et al., 1997; Schnee and Brown, 1998). Although other explanations are possible, our findings suggest that this might arise from a contribution by erg channels to the cortical neuron current. In view of the significance of M-like channels as potential targets for cognition-enhancing drugs (Zaczek and Saydoff, 1993), further information regarding the degree of heterogeneity in the molecular composition of the channels underlying M-like currents in different neurons would be helpful.
Footnotes
B.L. was supported by a Grant-In-Aid from the American Heart Association, and the other authors were supported by the United Kingdom Medical Research Council and the Wellcome Trust. We thank Misbah Malik-Hall, Brenda Browning, and Mariza Dayrell for tissue culture and Svjetlana Miocinovic (Biology Program, CalTech, Pasadena, CA) for participation in some experiments.
Correspondence should be addressed to Dr. A. A. Selyanko, Department of Pharmacology, University College London, Gower Street, London WC1E 6BT, UK.