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Previous Article | Next Article
The Journal of Neuroscience, November 15, 2002, 22(22):9698-9707
Regional Differences in Distribution and Functional Expression of Small-Conductance Ca2+-Activated K+ Channels in Rat Brain
Claudia A. Sailer1, Hua Hu3, Walter A. Kaufmann1, Maria Trieb1, Christoph Schwarzer2, Johan F. Storm3, and Hans-Günther Knaus1 1 Institute for Biochemical Pharmacology and 2 Institute for Pharmacology, University Innsbruck, A-6020 Innsbruck, Austria, and 3 Institute for Physiology, University of Oslo, N-0317 Oslo, Norway
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Small-conductance Ca2+-activated K+ (SK) channels are important for excitability control and afterhyperpolarizations in vertebrate neurons and have been implicated in regulation of the functional state of the forebrain. We have examined the distribution, functional expression, and subunit composition of SK channels in rat brain. Immunoprecipitation detected solely homotetrameric SK2 and SK3 channels in native tissue and their constitutive association with calmodulin. Immunohistochemistry revealed a restricted distribution of SK1 and SK2 protein with highest densities in subregions of the hippocampus and neocortex. In contrast, SK3 protein was distributed more diffusely in these brain regions and predominantly expressed in phylogenetically older brain regions. Whole-cell recording showed a sharp segregation of apamin-sensitive SK current within the hippocampal formation, in agreement with the SK2 distribution, suggesting that SK2 homotetramers underlie the apamin-sensitive medium afterhyperpolarizations in rat hippocampus.
Key words: SK channels; potassium channels; apamin; antibodies; afterhyperpolarization; subunit composition; distribution
INTRODUCTION
Molecular cloning of small-conductance Ca2+-activated K+ (SK) channels has revealed three genes, SK1-SK3 (Kohler et al., 1996
). When expressed in Xenopus oocytes, the resulting channels are voltage-insensitive and activated by submicromolar intracellular Ca2+ (Kohler et al., 1996
In many neurons, action potentials are followed by afterhyperpolarizations (AHPs) consisting of several phases, reflecting the activation of different K+ currents. Hippocampal pyramidal cells show three different AHPs: fast, medium (mAHP), and slow (sAHP) (Storm, 1987
To determine which SK proteins underlie the various ionic currents and AHPs, detailed information regarding the distributions of the SK subunits is required. However, so far our knowledge of these distributions in the brain has been based on in situ hybridization data (Kohler et al., 1996
In this study, we have used a combination of immunological, pharmacological, and electrophysiological tools to determine the distribution and functional expression of all three SK channel genes in rat brain. These results may help clarify unsolved discrepancies of functional and pharmacological properties of SK channels.
MATERIALS AND METHODS
Materials
[125I]Apamin (2175 Ci/mmol) was obtained from PerkinElmer Life Sciences (Boston, MA), and SuperSignal West dura extended substrate was from Pierce (Rockford, IL). Protein A-Sepharose, sodium cholate, peroxidase-conjugated goat anti-rabbit IgG (used for Western blots), and 3,3' diaminobenzidine were from Sigma (Munich, Germany). A monoclonal mouse IgG1 anti-calmodulin antibody (05-173) was purchased from Upstate Biotechnology (Lake Placid, NY). Horseradish peroxidase-coupled goat anti-rabbit IgG (0448) was purchased from Dako (Glostrup, Denmark). Apamin was bought from Calbiochem (San Diego, CA), and 9-fluorenylmethoxycarbonyl lysine core solid phase support was from NovaBiochem (Laeufelfingen, Switzerland). Cyanogen bromide (CNBr)-activated Sepharose 4B was obtained from Amersham Biosciences (Uppsala, Sweden). The M-channel blocker 10,10-bis(pyridinylmethyl)-9(10H)-anthracenone (XE991) was obtained from DuPont (Billerica, MA). All remaining drugs were from Sigma. Substances for slice electrophysiology were bath-applied by adding them to the superfusing medium.Antibody production and affinity purification
Polyclonal sera were raised against SK1 protein (GenBank accession number U69885), residue positions 12-29, using the sequence QPLGSGPGFLGWEPVDPE (anti-SK1(12-29)) and 515-532, using the sequence HLTTAAQSPQSHWLPTTA (anti-SK1(515-532)); SK2 protein (GenBank accession number U69882), residue position 538-555, using the sequence RDFIETQMENYDKHVTYN (anti-SK2(538-555)); and SK3 protein (GenBank accession number U69884), residue position 504-522, using the sequence ADTLRQQQQQLLTAFVEAR (anti-SK3(504-522)) (Kohler et al., 1996Immunoblot analysis
Immunoblot analysis was performed as described by Knaus et al. (1995)Immunocytochemistry
Immunocytochemical experiments were performed in slight variations to our previous study (Knaus et al., 1996Preparation of purified synaptic plasma membrane vesicles from rat whole brain or hippocampus
Rats (Sprague Dawley, 150-250 gm) were killed by CO2 inhalation and decapitated; their brains were rapidly removed; the hippocampus was dissected; and the tissue placed in ice-cold homogenization media (320 mM sucrose, 10 mM Tris-HCl, pH 7.4, 1 mM K2-EDTA, 10 µM PMSF, 10 µM benzamidine, and 1 µM pepstatin A). Synaptic plasma membrane vesicles were prepared by fractionated centrifugation of homogenated brain tissue followed by 7.5/10.0% Ficoll gradient centrifugation (to isolate intact synaptosomes) (Lai et al., 1977-conotoxin GVIA for N-type Ca2+ channels, [125I]iberiotoxin for high-conductance Ca2+-activated K+ channels, and [125I]apamin for small-conductance Ca2+-activated K+ channels). On average, specific activity of the final membrane preparation was enriched 8- to 12-fold compared with the respective starting material (data not shown).
Preparation of Xenopus oocyte membranes expressing SK channels
For membrane preparation, batches of 60-80 oocytes injected with SK1, SK2, or SK3 (Kohler et al., 199680°C until use.
Solubilization of rat brain SK channels, immunoprecipitation studies, and in vitro [125I]apamin binding studies
Solubilization. Rat brain synaptic plasma membrane vesicles were sedimented (45,000 × g, 15 min), and the resulting pellet was resuspended in (in mM): 5 Tris-HCl, pH 7.4, 0.1 PMSF, 1 iodoacetamide, and 0.1 benzamidine containing 4% (w/v) sodium cholate and 500 mM KCl at a final protein concentration of 20 mg/ml. After incubation, with intermittent mixing, at 1°C for 60 min, insoluble material was sedimented at 106,000 × g for 60 min. Immunoprecipitation and in vitro [125I]apamin binding studies. For all experiments, crude anti-SK1(12-29), anti-SK1(515-532), anti-SK2(538-555), and anti-SK3(504-522) serum or a combination thereof was prebound to an equal amount of packed protein A-Sepharose in radioimmunoassay (RIA) buffer (5 mM Tris-HCl, pH 7.4, 5 mM KCl, 0.1% BSA, and 0.3% sodium cholate) for 60-120 min under gentle rotation. The gel was washed three times with 1 ml of RIA buffer before the addition of sodium cholate-solubilized SK channels. The solubilized material was diluted twofold in RIA buffer to lower the detergent and KCl concentration and added to the prebound antibodies, and incubation was continued for 12 hr at 4°C. Each protein A-Sepharose pellet was split into six equal samples, and antibody-bound SK channels were determined by [125I]apamin binding (three samples for control binding and three samples for nonspecific binding). The incubation medium (200 µl) consisted of RIA buffer. Nonspecific binding was defined in the presence of 30 nM apamin, and incubation was performed at 4°C. After 60 min of incubation with the radioligand in the absence (control) or presence of apamin (nonspecific binding), the protein A-Sepharose was rapidly washed three times with ice-cold RIA buffer, and bound [125I]apamin was determined by gamma radiation counting. Under these conditions, a saturating concentration of anti-SK2(538-555) (e.g., 25 µl of serum) typically precipitated 11000-25000 cpm of [125I]apamin (<200 cpm in the presence of 30 nM apamin), whereas the respective preimmune serum precipitated <350 cpm of [125I]apamin (<200 cpm in the presence of 30 nM apamin). Coimmunoprecipitation and cross-blotting. Anti-SK2(538-555) and anti-SK3(504-522) antibodies were affinity-purified as described previously (Knaus et al., 1995Slice electrophysiology
Slice preparation. Young male Wistar rats (17-35 d) were deeply anesthetized with halothane before decapitation. Transverse hippocampal slices (400 µm thick) were prepared using a Vibratome (752M; Campden Instruments, Loughsborough, UK) and maintained in artificial CSF (ACSF) containing (in mM): 125 NaCl, 25 NaHCO3, 1.25 KCl, 1.25 KH2PO4, 1.5 MgCl2, 1 CaCl2, and 16 glucose and saturated with 95% O2 and 5% CO2. Whole-cell recording and drug application. During recording, the slices were kept at room temperature and superfused with ACSF of the above composition, except that the concentration of CaCl2 was raised to 2 mM. Whole-cell gigaohm seal recordings were obtained from CA1 pyramidal cells using the "blind" method. The patch pipettes were filled with a solution containing (in mM): 140 K-gluconate, 10 HEPES, 2 ATP Na salt, 0.4 GTP Na salt, and 2 MgCl2, resulting in a pipette resistance of 4-7 M. The cells were voltage-clamped using an Axopatch 1D amplifier (Axon Instruments, Foster City, CA), and signals were filtered at 2 kHz (
dI/dt)/V; where V is the amplitude of a negative voltage-clamp step (
Data acquisition, storage, and analysis
The data were acquired using pClamp 7.0 (Axon Instruments) at a sampling rate of 1 kHz, digitized (10 kHz), stored on videotapes (Instrutec VR-10), analyzed, and plotted using pClamp 7.0 and Origin 5.0 (Microcal). The peak of the mAHP current (ImAHP) was measured by averaging the amplitude measurements within a 10 msec time window 50 msec after the end of depolarizing step; this time window always corresponded to the peak of ImAHP. Because the time to peak was more variable for the sAHP current (IsAHP), we used a different method to measure its amplitude. The current trace within a time window that included IsAHP but excluded ImAHP was low-pass-filtered at 100 Hz to reduce the high-frequency noise, and the peak amplitude was determined at the time point at which the filtered IsAHP was maximal. Values are expressed as mean ± SEM. Two-tailed paired Student's t test was used for statistical analysis (= 0.05).
RESULTS
Characterization of SK-specific antibodies in immunoblot analysis of rat brain
Anti-SK1(12-29), anti-SK1(515-532), anti-SK2(538-555), and anti-SK3(504-522) sequence-directed antibodies against the pore-forming subunits of SK1, SK2, and SK3 channels were applied to investigate the presence and apparent molecular weight of their tissue-expressed gene products. All antibodies specifically recognized both the respective in vitro-translated SK channels (data not shown) and SK1, SK2, or SK3 protein after expression in Xenopus oocytes followed by isolation of the plasma membrane fraction (Fig. 1). In Xenopus oocytes, the respective SK antibodies recognized immunoreactive bands of 69 kDa (SK1), 64 kDa (SK2), and 67 kDa (SK3).
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Figure 1. Immunological identification of SK channel protein in rat hippocampus and Xenopus oocyte membranes: characterization of anti-SK antibodies in Western blotting experiments. Twenty micrograms of purified rat hippocampal synaptic plasma membrane vesicles or Xenopus oocyte membranes expressing SK1, SK2, or SK3 channels were separated by 10% SDS-PAGE and transferred to PVDF membranes. SK proteins were detected by the respective antibodies following standard procedures. SK1 protein, 65, 58, and 43 kDa in rat brain and 69 kDa in oocyte membranes (N-terminal AB); SK1 protein, 65 and 58 kDa in rat brain membranes (C-terminal AB); SK2 protein, 67 kDa in rat brain and 64 kDa in oocyte membranes; SK3 protein 70 kDa in rat brain and 67 kDa in oocyte membranes. AB, Antibody; I, immune serum; PI, preimmune serum; RB, rat brain membranes; OO, oocyte membranes;
In purified synaptic plasma membrane vesicles from rat whole brain, anti-SK1(12-29) stained three diffuse bands with apparent Mr values of 65, 58, and 43 kDa, whereas the respective C-terminal antibody anti-SK1(515-532) exclusively stained polypeptides with apparent Mr values of 65 and 58 kDa. An identical polypeptide pattern was observed for mouse whole-brain membranes (data not shown). In contrast, anti-SK2(538-555), and anti-SK3(504-522) stained single bands with overall Mr values of 67 and 70 kDa, respectively (Fig. 1). The observed Mr values for SK2 and SK3 channels are in good agreement with the deduced Mr values (SK2, 64 kDa; SK3, 63 kDa; for considerations regarding the polypeptides detected by anti-SK1(12-29) and anti-SK1(515-532), see Discussion). The immunostaining signal was substantially reduced by inclusion of 10 µM immunogenic peptide (data not shown) and not present when using the respective preimmune sera (Fig. 1).
Subunit composition of apamin-sensitive SK channels in rat brain
To investigate further the molecular components of SK channels in rat brain, these channels were solubilized with sodium cholate; the individual channel population was immunoprecipitated by the corresponding antibodies; and the amount of channel precipitated was quantified by [125I]apamin binding. In all cases, the respective preimmune sera precipitated <5% compared with the corresponding immune sera (Fig. 2B). Although anti-SK2(538-555) and anti-SK3(504-522) yielded saturable levels of [125I]apamin-binding precipitation, both anti-SK1(12-29) and anti-SK1(515-532) failed to immunoprecipitate [125I]apamin binding to a significant extent (Fig. 2A). Anti-SK2(538-555) precipitated 71 ± 5% (n = 3) of soluble apamin receptors, whereas anti-SK3(504-522) precipitated 29 ± 7% (n = 3) of the sites. However, the combination of both antisera resulted in strict additivity, indicating complete segregation of SK2 and SK3 channels into individual channel populations (Fig. 2B). Western blot analysis of the remaining supernatant indicated complete clearance from soluble apamin-sensitive SK channels (data not shown). Additional support stems from cross-blotting experiments using anti-SK2(538-555) and anti-SK3(504-522) immunoaffinity columns (Fig. 2C). Although anti-SK2(538-555) is clearly capable of retaining SK2 channels, this antibody failed to coimmunoprecipitate SK3 channels. In support of these data, anti-SK3(504-522) immunoaffinity purified solely SK3 channels; however, no SK2 channels were detected through this cross-blotting approach.
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Figure 2. Immunoprecipitation of detergent-solubilized SK channel complexes. A, Cholate-solubilized SK channels were immunoprecipitated using increasing concentrations of anti-SK1(12-29) ( ), anti-SK2(538-555) (
), or anti-SK3(504-522) (
) antibodies immobilized on protein A-Sepharose. Immunoprecipitated channels were quantified by [125I]apamin binding to antibody-bound SK channels. In this experiment, anti-SK2(538-555) saturably precipitated 2100 cpm, whereas anti-SK3(504-522) immobilized 930 cpm. Anti-SK1(12-29) was unable to precipitate any [125I]apamin binding. One representative experiment is shown. PI, Preimmune serum. B, Cholate-solubilized neuronal SK channels were immunoprecipitated by a saturating amount of anti-SK2(538-555) and anti-SK3(504-522) antibodies or a combination thereof. The extent of immunoprecipitation was quantified by [125I]apamin binding to antibody-immobilized SK channels. Exclusively anti-SK2(538-555) and anti-SK3(504-522) antibodies were capable of immunoprecipitating [125I]apamin binding, whereas the corresponding preimmune sera did not immobilize soluble apamin-sensitive SK channels. C, Solubilized neuronal SK channels were immunoaffinity-purified by column chromatography using anti-SK2(538-555) or anti-SK3(504-522). Eluates were analyzed by Western blotting using anti-SK antibodies as indicated. Note that the SK3 antibody does not recognize anti-SK2-immunoprecipitated material and vice versa. D, Immunoblot analysis of anti-SK2(538-555)- and anti-SK3(504-522)-immunoprecipitated material for the presence of calmodulin. Equal amounts of detergent-solubilized material were subjected to immunoprecipitation. Immunoreactivity observed in the control lane corresponds to monomeric and dimeric calmodulin.
Because [125I]apamin failed to detect SK1 channels being precipitated by the respective antibodies, this cross-blotting approach was also attempted. However, neither of the anti-SK antibodies was capable of immunoprecipitating detergent-solubilized SK1 protein. This finding indicates that none of our anti-SK1 antibodies is suitable for immunoprecipitation experiments; therefore, no conclusion regarding subunit composition or association of SK1 channels with calmodulin can be drawn.
After providing evidence that SK2 and SK3 subunits do not coassemble to form heterotetrameric SK2/SK3 channels, we next investigated whether calmodulin is constitutively bound to rat brain SK channels. As shown in Figure 2D, both anti-SK2(538-555) and anti-SK3(504-522) coimmunoprecipitated calmodulin. This precipitation was specific, because a corresponding amount of the respective preimmune serum failed to precipitate calmodulin. The result with the anti-SK3 antibody is in good agreement with a previous report (Xia et al., 1998
Regional distribution of SK protein in neocortex and hippocampal formation
Specificity of immunostaining
The neuronal distribution pattern of all three subunits was investigated by immunohistochemical analysis (Figs. 3, 4). The characteristic immunostaining pattern fulfilled the specificity criteria, because it was not observed with the corresponding preimmune sera (Fig. 3) or in the presence of excess immunogenic peptide (data not shown). It is beyond the scope of this paper to provide a detailed description of the distribution of SK1-, SK2-, and SK3-IR in all brain regions. However, the salient features of the immunohistochemical staining patterns of these three proteins are described below.
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Figure 3. Coronal sections showing the distribution of SK1-SK3 protein in rat brain. Low-magnification microphotographs show the overall distribution of SK1-SK3 immunoreactivity in coronal brain sections. Adjacent sections (40 µm) were stained with affinity-purified anti-SK1(12-29) (2.0 ng/µl IgG), anti-SK2(538-555) 1:6000 (crude serum), and anti-SK3(504-522) (1.3 ng/µl IgG). Nonspecific immunostaining was assessed using preimmune serum. Immune serum preadsorbed to immunogenic peptide yielded essentially identical results. 3V, Third ventricle; Amyg, amygdala, CM, centromedial thalamic nucleus; CPu, caudate putamen; Cx, neocortex; Hi, hippocampus; LD, laterodorsal thalamic nucleus; LH, lateral hypothalamic area; PV, paraventricular thalamic nucleus; Rt, reticular thalamic nucleus; VP, ventroparietal thalamic nucleus. Scale bar, 1000 µm.
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Figure 4. Differential distribution of SK1-SK3 protein in sections of the rat brain: expression of SK proteins in subsets of neurons. A-C, SK1-SK3-IR in layers IV-VI of the frontoparietal cortex (coronal brain section). D-F, SK1-SK3 localization in the CA3 region of the hippocampus. G-I, Localization of SK1-SK3 protein within the hippocampus proper. J-L, Distribution of SK1-SK3 protein within the dentate gyrus. gl, Granule cell layer; ml, molecular layer; pl, polymorphic layer; sl, stratum lucidum; sp, stratum pyramidale; so, stratum oriens; sr, stratum radiatum. Scale bar: A-C, 45 µm; D-F, J-L, 100 µm; G-I, 400 µm.
Expression of SK1 protein
To obtain a distribution profile of all SK1 proteins independently of alternate splicing, the anti-SK1(12-29) antibody was used for all distribution studies. In the neocortex, almost all SK1 IR was restricted to fibers extending from layer V to layer I (Fig. 4A). The staining appeared to be associated with both the proximal and distal dendrites of the layer V pyramidal cells. Little or no IR could be observed in perikarya in this brain region. However, the highest levels of SK1 protein were expressed in the hippocampal formation, again showing staining associated with the neuropil (Fig. 4D,G,J). Virtually no immunostaining was associated with granule and pyramidal cell somata. The molecular layer (inner, middle, and outer parts) of the dentate gyrus, containing the dendrites of granule, basket, and polymorphic cells as well as perforant path terminals, revealed the most prominent staining (Fig. 4J). Dense IR could also be observed within the mossy fiber system, with highest levels in the stratum lucidum of the CA3 area. This layer contains three principal structures: pyramidal cell dendrites, mossy fiber axons, and synaptic complexes. Somewhat lower concentrations of the SK1 protein could be detected in stratum oriens and stratum radiatum (Fig. 4D). These regions contain, for example, the dendrites of the pyramidal cells as well as the Schaffer collaterals. Interestingly, the signal was slightly discontinuous at the junction between the CA1 and CA3 regions, with a somewhat higher density of IR in CA1 (Fig. 4G).Expression of SK2 protein
SK2-IR in the neocortex could be predominantly observed in pyramidal cells of layer V. Distinct staining was associated with the soma as well as with the proximal portion of the dendritic tree (Fig. 4B). All other neocortical compartments appeared to be almost devoid of SK2-IR. In the hippocampal formation, SK2-IR was mainly enriched in the CA1-CA3 region (hippocampus proper) but predominately spared the dentate gyrus (Fig. 4H). Within the hippocampus proper, the highest level of SK2 protein was present in the stratum oriens (especially in the layer of the proximal dendrites of pyramidal cells), whereas the strata radiatum and pyramidale showed intermediate to low levels of immunoreactivity, respectively. No SK2 immunostaining was associated with the stratum lucidum of CA3 (Fig. 4E). As mentioned before, the dentate gyrus (DG) revealed only low levels of SK2 protein. Faint staining could be observed in the molecular layer, whereas the DG granule cell layer was virtually devoid of SK2-IR (Fig. 4K). Additionally, a limited number of hippocampal interneurons were found to expose SK2-IR. Most of these were found in the stratum oriens, although scattered neurons could be observed throughout the hippocampus.Expression of SK3 protein
In contrast to SK1 and SK2 protein, the anti-SK3(504-522) antibody revealed only faint staining throughout the entire neocortex. No particular enrichment in any layer could be observed. The most prominent feature was the staining of varicose fibers in all neocortical layers (Fig. 4C). The hippocampal formation showed moderate levels of SK3-IR compared with its expression in the basal ganglia or thalamus. SK3-IR was almost uniformly distributed throughout this brain region but with distinct fiber staining within the hilus and the terminal field of mossy fibers (Fig. 4I,L). This suggests an axonal or presynaptic localization of SK3 protein for areas that were mostly devoid of SK2 protein. Virtually no IR could be found for the DG granule cell layer and the superficial molecular layer (Fig. 4L). Moderate levels of SK3-IR were also associated with the stratum lacunosum moleculare, a layer in which the perforant path fibers from the entorhinal cortex terminate. A low level of immunostaining was present in the strata oriens and radiatum of CA1-CA3, whereas no IR could be detected in the pyramidal cell layer (Fig. 4F,I). Taken together, the staining patterns of SK1 and SK2 protein were found to be distinct; however, they overlapped in some brain regions. SK3 protein was distributed mostly reciprocally without any significant extent of overlap to SK1 and SK2.Functional expression of SK channels in rat brain
Given the prominent expression of SK1-SK3 protein in the rat hippocampal formation, we focused our electrophysiological experiments on this brain region.
Whole-cell somatic recordings were obtained from CA1 and CA3 pyramidal cells and granule cells of the dentate gyrus in rat hippocampal slices. To compare the Ca2+-activated K+ currents (AHP currents; Pennefather et al., 1985
Calcium-activated tail currents were elicited by a brief (100 msec) depolarizing voltage step, which reliably triggered Ca2+ influx in the form of an unclamped Ca2+ action current (see Materials and Methods; Pedarzani and Storm, 1993
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Figure 5. Apamin-sensitive and -insensitive AHP currents in hippocampal pyramidal cells and DG cells. Typical AHP currents recorded in a CA1 pyramidal cell (A), a CA3 pyramidal cell (B), and a DG granule cell (C) in rat hippocampal slices are shown. Each cell was voltage-clamped at -55 mV in the presence of TTX and TEA in the extracellular medium to suppress the Na+- and BK-channel-mediated currents. The AHP currents were elicited by a brief depolarizing voltage step (100 msec to 0 mV) once every 60 sec. The depolarizing step elicited biphasic outward tail currents in all three cell types (Control): an early tail current of medium duration was followed by an IsAHP lasting several seconds. The early current was much larger in CA1 and CA3 pyramidal cells than in DG granule cells. Bath application of 100 nM apamin abolished the early outward tail current in the CA1 and CA3 pyramidal cells but had little or no effect in the DG cells. The records before and after apamin application are compared (Superimposed) at two different time scales to show the time course of both components. (The current records in the CA3 cell appeared "noisy" because of a large number of spontaneous miniature synaptic currents.) D-G, Summary data comparing currents in CA1 pyramidal cells (n = 6), CA3 pyramidal cells (n = 9), and DG granule cells (n = 6). D, Peak amplitudes of the apamin-sensitive tail current obtained by digital subtraction of records taken before and after application of 100 nM apamin. The current was measured 50-60 msec after the end of the depolarizing step. E, Peak amplitudes of the apamin-insensitive sAHP current. F, G, Current densities obtained by dividing the measurements shown in D and E, respectively, by the whole-cell capacitance measured in each cell. F, Current densities for the apamin-sensitive tail current. G, Current densities for the apamin-insensitive sAHP current. All currents (A-G) were recorded without cAMP in the pipette and in extracellular medium with 1 µM TTX and 5 mM TEA. D-G, Mean values and SEM (error bars) for the peak tail currents.
Figure 5 shows typical AHP currents recorded in a CA1 pyramidal cell (Fig. 5A), a CA3 pyramidal cell (Fig. 5B), and a DG granule cell (Fig. 5C). The CA1 and CA3 pyramidal cells showed a large mAHP current followed by a smaller sAHP current. In contrast, the DG cells showed little or no distinct early (mAHP) current, although the IsAHP amplitude was similar to that of CA1 and CA3 pyramidal cells (Fig. 5C). Furthermore, whereas bath application of 100 nM apamin blocked the large mAHP current in both the CA1 and CA3 pyramidal cells, this toxin had only a small effect on the early tail currents of the DG granule cells (Fig. 5C). This indicates that the apamin-sensitive SK current is substantially smaller in the latter cell type. In contrast, the sAHP current was relatively similar both in amplitude and time course in the three cell types (Fig. 5, Table 1). Apamin (10 µM) had no measurable effect on IsAHP in any of the three cell types (Fig. 5A-C), indicating that this current is generated by apamin-resistant channels (Lancaster and Nicoll, 1987
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Table 1. Cells recorded without cAMP in the pipette In the CA3 cells, apamin unmasked an inward tail current (Fig. 5B). The nature of this current was not determined in our study, but it is likely to be a Ca2+ or Na+ current, possibly through Ca2+-activated nonselective cation channels (Partridge and Swandulla, 1993
To study the apamin-sensitive current, IaAHP, in relative isolation, we performed the remaining experiments under conditions that suppressed IsAHP as well as other K+ currents (Fig. 6). In these experiments, M-, BK-, and delayed rectifier-type K+ currents were suppressed by bath application of 10 µM XE991 and 5 mM TEA. In addition, IsAHP was suppressed by inclusion of cAMP analogues [in µM: 100 cAMP or 100 8 chlorophenylthio (CPT)-cAMP] in the intracellular medium in the recording pipette (Madison and Nicoll, 1986
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Figure 6. Apamin-sensitive currents in CA1 and CA3 pyramidal cells and DG granule cells recorded after suppression of the sAHP BK- and M-currents. To study the apamin-sensitive currents in relative isolation, the IsAHP BK current and M-current were suppressed by including 100 µM cAMP (cAMP or 8CPT-cAMP) in the intracellular medium of the recording pipette and 5 mM TEA plus 10 µM XE991 in the extracellular medium throughout each experiment. Tail currents from representative CA1 (A) and CA3 (B) pyramidal cells and a DG granule cell (C) are shown. The currents were elicited and recorded using the same voltage-clamp protocol as in Figure 5 (holding potential, -55 mV; 100 msec step). For each cell (A-C), records before (Control) and after application of 100 nM apamin are shown. Note that the DG granule cells showed no net outward tail current under these conditions. Furthermore, the apamin-sensitive current isolated by digital subtraction (Subtracted) was far smaller in the DG neurons than in the CA1 and CA3 neurons and decayed more slowly in CA3 than in CA1 cells. Superimposed, Comparison of the records before and after apamin application. D, E, Comparison between typical time courses of the effect of apamin (100 nM) application (gray bar) on the early tail current (normalized; control = 100%) in a pyramidal cell (D) and a DG granule cell (E). The apamin effects in CA1 and CA3 pyramidal cells were similar (the example shown in D is from a CA3 cell), whereas the effect was much weaker in DG cells. Note in both cell types the slight time-dependent run-down of the currents. In pyramidal cells, an initial increase ("run-up") of the current amplitude was sometimes observed (D; 0-3 min). F, G, Summary data comparing apamin-sensitive currents (F) and current densities (G) in CA1 pyramidal cells (n = 9), CA3 pyramidal cells (n = 8), and DG granule cells (n = 7). D, Peak amplitudes of the apamin-sensitive tail current obtained by subtraction of records before and after application of 100 nM apamin. G, Current densities obtained by dividing the measurements shown in F by the whole-cell capacitance measured in each cell.
In response to the same voltage-clamp protocol as used in Figure 5, the CA1 and CA3 pyramidal cells still showed an outward mAHP current, whereas the DG cells showed only an inward tail current under these conditions. Application of apamin again suppressed virtually all mAHP current in CA1 (n = 9) and CA3 (n = 8) pyramidal cells but had only a small effect in the DG granule cells. Furthermore, 100-600 µM D-tubocurare applied in addition to 100 nM apamin produced no further effect (n = 20), suggesting that 100 nM is a saturating concentration of apamin under these conditions (Kohler et al., 1996
The apamin-sensitive current was somewhat larger and more slowly decaying in the CA3 than in the CA1 pyramidal cells (Figs. 5, 6A,B). Thus, for cells recorded with cAMP, the decay time constant of IaAHP was 177 ± 30 msec in the CA1 (n = 9) versus 297 ± 23 msec in CA3 (n = 8; p = 0.008; Tables 2, 3). A similar difference was also found in cells recorded without cAMP (Table 1). In addition to IaAHP, two of the eight CA3 cells recorded with cAMP also showed a slower apamin-insensitive outward current component, which was not characterized further in this study.
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Table 2. Cells recorded with cAMP in the pipette (IsAHP suppressed)
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Table 3. p values from statistical comparisons (two-tailed paired Student's t test) The small size of the apamin-sensitive SK current in the DG granule cells was apparently not attributable to failure of Ca2+ influx during the depolarizing step, because DG granule cells showed a clear Ca2+ spike during each voltage step (data not shown), as well as a prominent IsAHP, which was also dependent on Ca2+ influx (Fig. 5C, Table 1) (Haas and Rose, 1987
The difference in whole-cell current is probably related to differences in cell size. To relate the current measurements to the surface membrane area, we calculated the membrane capacitance for each cell from capacitative transients evoked by hyperpolarizing voltage steps (see Materials and Methods) and divided the currents by the capacitance. For the IaAHP, the current densities thus obtained in the CA1, CA3, and DG cells were 0.80, 0.75, and 0.38 pA/pF, respectively. Thus, the IaAHP density in the DG granule cells appears to be only approximately half of that in the CA pyramidal cells (Fig. 6G). In contrast, the average density of the sAHP current was somewhat larger in the DG granule cells (0.45 ± 0.11 pA/pF) than in the CA1 and CA3 pyramidal cells (0.29 ± 0.08 and 0.16 ± 0.04 pA/pF, respectively), although the difference was not statistically significant in our data (Fig. 5G, Tables 1-3).
In conclusion, there seems to be a substantial difference in the size of the apamin-sensitive SK current between the CA1 and CA3 hippocampal pyramidal cells on one hand and the DG granule cells on the other, whereas the apamin-resistant sAHP current shows no such difference. This holds both for the total current per cell and when corrected for cell size (membrane capacitance, reflecting surface area).
DISCUSSION
This report presents the first distribution profile for all SK channel subunits in a mammalian brain. The data indicate distinct, although partly overlapping, distributions for the three SK subunits and suggest that the apamin-sensitive medium afterhyperpolarization of the hippocampal pyramidal cells is mainly attributable to SK2 protein.
To obtain a complete antibody panel for the individual SK channel subunits, we raised a total of 14 sequence-directed anti-SK channel antibodies of which four antibodies were used to perform this study. The difficulties obtaining suitable SK channel antibodies with high selectivity were mostly attributable to the very low expression density of SK channel protein in mammalian brain (based on radioligand binding data using the SK channel ligand [125I]apamin). This toxin labels only 20-40 fmol of binding sites/mg of protein, a density 10 times lower than for BK-channels (as measured by [125I]iberiotoxin binding; Koschak et al., 1997
Additional complications stem from the fact that the rodent SK1 gene (but not the SK2 and SK3 genes) undergoes extensive alternative splicing. Mouse and rat brain express at least eight 3'-variant SK1 transcripts with additional heterogeneity in the 5' region (Shmukler et al., 2001
After having established that our antibodies specifically recognize their respective target proteins, we used them to establish the distribution of all known SK channels. The three SK channel subunits displayed distinct although sometimes overlapping distribution. Most of the higher brain regions such as the neocortex and hippocampus showed expression of both SK1 and SK2 channels, whereas phylogenetically older brain regions (e.g., the thalamus, basal ganglia, cerebellum, and brainstem) showed high levels of SK3 expression. The strong expression of SK3 channel protein in the basal ganglia and brainstem was also previously observed for the mouse brain (Bond et al., 2000
A particular informative distribution pattern was observed for the hippocampal formation. High levels of SK2 expression in the CA1-CA3 fields contrasted with the low levels in the dentate gyrus. Conversely, for SK1 protein, high levels were detected in the DG with lower levels in CA1-CA3. Immunoreactivity for these SK proteins was found in regions containing densely packed dendrites of pyramidal cells (SK1- and SK2-IR) or DG granule cells (SK1-IR). Considering that the granule cells are more numerous and smaller, with thinner dendritic shafts, than the pyramidal cells (Amaral et al., 1990
SK3 protein in rat hippocampus is expressed only at moderate to low levels (Figs. 3, 4) with the most prominent staining observed in the mossy fiber system. This distribution in conjunction with the characteristic immunostaining of varicose fibers throughout the hippocampal formation suggests most likely an axonal or presynaptic localization of SK3 protein. This proposed subcellular targeting is supported by recent colocalization studies in cultured neonatal hippocampal neurons in which SK3 protein clearly coresides with established presynaptic marker proteins (e.g., synapsin; Obermair et al., 2001
On the basis of the distinct distribution pattern in the hippocampal formation, this brain region was chosen for functional investigations. Whole-cell patch-clamp recordings revealed a striking difference in the functional expression of the apamin-sensitive outward current IaAHP between the DG granule cells and the CA1-CA3 pyramidal cells. Whereas the pyramidal cells showed a robust IaAHP of ~100 pA (80-130 pA in CA1 and 120-150 pA in CA3), IaAHP was an order of magnitude smaller in the granule cells (~8 pA under normal conditions) (Figs. 5, 6, Table 1). Even when corrected for the membrane capacitance of the cells (which is approximately proportional to their surface area), the currents (i.e., current densities) were still approximately twice as high in CA1-CA3 as in DG (~0.8 pA/pF in CA1-CA3 vs 0.4 pA/pF in DG). In contrast, the average density of the slow AHP current was somewhat larger in the DG than in CA1-CA3.
The apamin-sensitive SK current (~30 pA) detected in DG granule cells was significantly enhanced when the cells were perfused with cAMP analogues and other outward currents were suppressed (p = 0.002). This difference and the increased mean IaAHP in the pyramidal cells treated with cAMP may reflect a cAMP-induced upregulation of SK channels (as suggested for CA1 cells; Stocker et al., 1999
There seems to be a close agreement between the functional expression of apamin-sensitive current and the distribution of SK2 protein in the hippocampal principal neurons. Thus, the SK2 protein levels, as well as the apamin-sensitive current amplitudes, were highest in CA1-CA3 and substantially lower in the DG. In contrast, the differences in currents do not match the SK3 protein distribution, which was rather uniform throughout the entire hippocampal formation. This suggests that SK2 underlies the apamin-sensitive mAHP component of the CA1 and CA3 pyramidal cells. Because only SK2 homomultimers were detected by coimmunoprecipitation (Fig. 2B,C), it is likely that this channel type underlies the apamin-sensitive mAHP and, hence, the apamin-sensitive early spike frequency adaptation in the hippocampal pyramidal cells. However, it remains to be determined whether SK1 protein contributes to the apamin-sensitive AHP in the DG granule cells, where this SK species is more strongly expressed.
Why does the decay time course of the apamin-sensitive current differ between CA1 and CA3 pyramidal cells? This seems to most simply be explained by different Ca2+ dynamics, subcellular distribution of SK2 channels, or both, between the two cell types. The time course of the SK2 and SK3 channel activity is known to closely follow the rise in intracellular Ca2+ (Vergara et al., 1998
The relatively large sAHP current density in DG granule cells compared with CA1-CA3 pyramidal cells seems to approximately parallel the high levels of SK1 protein in the DG relative to CA1-CA3. This, along with the lower apamin sensitivity of homomeric SK channels, may seem to support the hypothesis that SK1 underlies the apamin-insensitive sAHP. However, this idea seems still difficult to reconcile with the observation that the hippocampal sAHP seems to be entirely resistant to high concentrations of apamin, which completely block the homomultimeric SK1 channels tested in different expression systems (Shah and Haylett, 2000a
) subunits that substantially alter the toxin sensitivity of the SK channel complex, such as the BK-
FOOTNOTES Received July 8, 2002; revised Sept. 4, 2002; accepted Sept. 6, 2002.
This work was supported by European Community Grants BMH4-CT97-2118 and QLRT-1999-01356 (J.F.S. and H.-G.K), Austrian Research Foundation Grant P14954-PHA (H.-G.K), the Norwegian Medical Research Council, and the Nansen and Odd Fellow Foundations. This report is part of the PhD theses of C.A.S. and H.H. We thank Dr. Hartmut Glossmann for continuous support. Xenopus oocyte membranes were kindly supplied by Dr. Dan Klaerke, Pannum Institute (Copenhagen, Denmark).
Correspondence should be addressed to Hans-Günther Knaus, Institut für Biochemische Pharmakologie, Peter-Mayr Strasse 1, A-6020 Innsbruck, Austria. E-mail: hans.g.knaus{at}uibk.ac.at.
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