Increasing small conductance Ca2+-activated potassium channel activity reverses ischemia-induced impairment of long-term potentiation.

Global cerebral ischemia following cardiac arrest and cardiopulmonary resuscitation (CA/CPR) causes injury to hippocampal CA1 pyramidal neurons and impairs cognition. Small conductance Ca(2+)-activated potassium channels type 2 (SK2), expressed in CA1 pyramidal neurons, have been implicated as potential protective targets. Here we showed that, in mice, hippocampal long-term potentiation (LTP) was impaired as early as 3 h after recovery from CA/CPR and LTP remained impaired for at least 30 days. Treatment with the SK2 channel agonist 1-Ethyl-2-benzimidazolinone (1-EBIO) at 30 min after CA provided sustained protection from plasticity deficits, with LTP being maintained at control levels at 30 days after recovery from CA/CPR. Minimal changes in glutamate release probability were observed at delayed times after CA/CPR, implicating post-synaptic mechanisms. Real-time quantitative reverse transcriptase-polymerase chain reaction indicated that CA/CPR did not cause a loss of N-methyl-D-aspartate (NMDA) receptor mRNA at 7 or 30 days after CA/CPR. Similarly, no change in synaptic NMDA receptor protein levels was observed at 7 or 30 days after CA/CPR. Further, patch-clamp experiments demonstrated no change in functional synaptic NMDA receptors at 7 or 30 days after CA/CPR. Electrophysiology recordings showed that synaptic SK channel activity was reduced for the duration of experiments performed (up to 30 days) and that, surprisingly, treatment with 1-EBIO did not prevent the CA/CPR-induced loss of synaptic SK channel function. We concluded that CA/CPR caused alterations in post-synaptic signaling that were prevented by treatment with the SK2 agonist 1-EBIO, indicating that activators of SK2 channels may be useful therapeutic agents to prevent ischemic injury and cognitive impairments.

SK2 and SK3 expression differentially affect firing frequency and precision in dopamine neurons.

The firing properties of dopamine (DA) neurons in the substantia nigra (SN) pars compacta are strongly influenced by the activity of apamin-sensitive small conductance Ca(2+)-activated K(+) (SK) channels. Of the three SK channel genes expressed in central neurons, only SK3 expression has been identified in DA neurons. The present findings show that SK2 was also expressed in DA neurons. Immuno-electron microscopy (iEM) showed that SK2 was primarily expressed in the distal dendrites, while SK3 was heavily expressed in the soma and, to a lesser extent, throughout the dendritic arbor. Electrophysiological recordings of the effects of the SK channel blocker apamin on DA neurons from wild type and SK(-/-) mice show that SK2-containing channels contributed to the precision of action potential (AP) timing, while SK3-containing channels influenced AP frequency. The expression of SK2 in DA neurons may endow distinct signaling and subcellular localization to SK2-containing channels.

Selective cognitive deficits and reduced hippocampal brain-derived neurotrophic factor mRNA expression in small-conductance calcium-activated K+ channel deficient mice.

Small-conductance calcium-activated K(+) channels 1-3 (SK1-3) are important for neuronal firing regulation and are considered putative CNS drug targets. For instance non-selective SK blockers improve performance in animal models of cognition. The SK subtype(s) involved herein awaits identification and the question is difficult to address pharmacologically due to the lack of subtype-selective SK-channel modulators. In this study, we used doxycycline-induced conditional SK3-deficient (T/T) mice to address the cognitive consequences of selective SK3 deficiency. In T/T mice SK3 protein is near-eliminated from the brain following doxycycline treatment. We tested T/T and wild type (WT) littermate mice in five distinct learning and memory paradigms. In Y-maze spontaneous alternations and five-trial inhibitory avoidance the performance of T/T mice was markedly inferior to WT mice. In contrast, T/T and WT mice performed equally well in passive avoidance, object recognition and the Morris water maze. Thus, some aspects of working/short-term memory are disrupted in T/T mice. Using in situ hybridization, we further found the cognitive deficits in T/T mice to be paralleled by reduced brain-derived neurotrophic factor (BDNF) mRNA expression in the dentate gyrus and CA3 of the hippocampus. BDNF mRNA levels in the frontal cortex were not affected. BDNF has been crucially implicated in many cognitive processes. Hence, the biological substrate for the cognitive impairments in T/T mice could conceivably entail reduced trophic support of the hippocampus.

SK3 K+ channel-deficient mice have enhanced dopamine and serotonin release and altered emotional behaviors.

SK3 K(+) channels influence neuronal excitability and are present in 5-hydroxytryptamine (5-HT) and dopamine (DA) nuclei in the brain stem. We therefore hypothesized that SK3 channels affect 5-HT and DA neurotransmission and associated behaviors. To explore this, we used doxycycline-induced conditional SK3-deficient (T/T) mice. In microdialysis, T/T mice had elevated baseline levels of striatal extracellular DA and the metabolites dihydroxyphenylacetic acid and homovanillic acid. While baseline hippocampal extracellular 5-HT was unchanged in T/T mice, the 5-HT response to the 5-HT transporter inhibitor citalopram was enhanced. Furthermore, baseline levels of the 5-HT metabolite 5-hydroxyindoleacetic acid were elevated in T/T mice. T/T mice performed equally to wild type (WT) in most sensory and motor tests, indicating that SK3 deficiency does not lead to gross impairments. In the forced swim and tail suspension tests, the T/T mice displayed reduced immobility compared with WT, indicative of an antidepressant-like phenotype. Female T/T mice were more anxious in the zero maze. In contrast, anxiety-like behaviors in the open-field and four-plate tests were unchanged in T/T mice of both sexes. Home cage diurnal activity was also unchanged in T/T mice. However, SK3 deficiency had a complex effect on activity responses to novelty: T/T mice showed decreased, increased or unchanged activity responses to novelty, depending on sex and context. In summary, we report that SK3 deficiency leads to enhanced DA and 5-HT neurotransmission accompanied by distinct alterations in emotional behaviors.

Small-conductance, Ca(2+) -activated K+ channel 2 is the key functional component of SK channels in mouse urinary bladder.

Small-conductance Ca(2+)-activated K(+) (SK) channels play an important role in regulating the frequency and in shaping urinary bladder smooth muscle (UBSM) action potentials, thereby modulating contractility. Here we investigated a role for the SK2 member of the SK family (SK1-3) utilizing: 1) mice expressing beta-galactosidase (beta-gal) under the direction of the SK2 promoter (SK2 beta-gal mice) to localize SK2 expression and 2) mice lacking SK2 gene expression (SK2(-/-) mice) to assess SK2 function. In SK2 beta-gal mice, UBSM staining was observed, but staining was undetected in the urothelium. Consistent with this, urothelial SK2 mRNA was determined to be 4% of that in UBSM. Spontaneous phasic contractions in wild-type (SK2(+/+)) UBSM strips were potentiated (259% of control) by the selective SK channel blocker apamin (EC(50) = 0.16 nM), whereas phasic contractions of SK2(-/-) strips were unaffected. Nerve-mediated contractions of SK2(+/+) UBSM strips were also increased by apamin, an effect absent in SK2(-/-) strips. Apamin increased the sensitivity of SK2(+/+) UBSM strips to electrical field stimulation, since pretreatment with apamin decreased the frequency required to reach a 50% maximal contraction (vehicle, 21 +/- 4 Hz, n = 6; apamin, 12 +/- 2 Hz, n = 7; P < 0.05). In contrast, the sensitivity of SK2(-/-) UBSM strips was unaffected by apamin. Here we provide novel insight into the molecular basis of SK channels in the urinary bladder, demonstrating that the SK2 gene is expressed in the bladder and that it is essential for the ability of SK channels to regulate UBSM contractility.

Small-conductance calcium-activated potassium currents in mouse hyperexcitable denervated skeletal muscle.

1. Hyperexcitability in denervated skeletal muscle is associated with the expression of SK3, a small-conductance Ca2+-activated K+ channel (SK channel). SK currents were examined in dissociated fibres from flexor digitorum brevis (FDB) muscle using the whole-cell patch clamp configuration. 2. Depolarization activated a K+-selective, apamin-sensitive and iberiotoxin-insensitive current, detected as a tail current upon repolarization, in fibres from denervated but not innervated muscle. Dialysis of the fibres with 20 mM EGTA in the patch pipette solution eliminated the tail current, consistent with this current reflecting Ca2+-activated SK channels expressed only in denervated muscle. 3. Activation of SK tail currents depended on the duration of the depolarizing pulse, consistent with a rise in intracellular Ca2+ due to release from the sarcoplasmic reticulum (SR) and influx through voltage-gated Ca2+ channels. 4. The envelope of SK tail currents was diminished by 10 microM ryanodine for all pulse durations, whereas 2 mM cobalt reduced the SK tail current for pulses greater than 80 ms, demonstrating that Ca2+ release from the SR during short pulses primarily activated SK channels. 5. In current clamp mode with the resting membrane potential set at -70 mV, denervation decreased the action potential threshold by approximately 8 mV. Application of apamin increased the action potential threshold in denervated fibres to that measured in innervated fibres, suggesting that SK channel activity modulates the apparent action potential threshold. 6. These results are consistent with a model in which SK channel activity in the T-tubules of denervated skeletal muscle causes a local increase in K+ concentration that results in hyperexcitability.

ATP-dependent activation of the intermediate conductance, Ca2+-activated K+ channel, hIK1, is conferred by a C-terminal domain.

We previously demonstrated that hIK1 is activated directly by ATP in excised, inside-out patches in a protein kinase A inhibitor 5-24 dependent manner, suggesting a role for phosphorylation in the regulation of this Ca(2+)-dependent channel. However, mutation of the single consensus cAMP-dependent protein kinase phosphorylation site (S334A) failed to modify the response of hIK1 to ATP (Gerlach, A. C., Gangopadhyay, N. N., and Devor, D. C. (2000) J. Biol. Chem. 275, 585-598). Here we demonstrate that ATP does not similarly activate the highly homologous Ca(2+)-dependent K(+) channels, hSK1, rSK2, and rSK3. To define the region of hIK1 responsible for the ATP-dependent regulation, we generated a series of hIK1 truncations and hIK1/rSK2 chimeras. ATP did not activate a chimera containing the N terminus plus S1-S4 from hIK1. In contrast, ATP activated a chimera containing the hIK1 C-terminal amino acids His(299)-Lys(427). Furthermore, truncation of hIK1 at Leu(414) resulted in an ATP-dependent channel, whereas larger truncations of hIK1 failed to express. Additional hIK1/rSK2 chimeras defined the minimal region of hIK1 required to confer complete ATP sensitivity as including amino acids Arg(355)-Ala(413). An alanine scan of all non-conserved serines and threonines within this region failed to alter the response of hIK1 to ATP, suggesting that hIK1 itself is not directly phosphorylated. Additionally, substitution of amino acids Arg(355)-Met(368) of hIK1 into the corresponding region of rSK2 resulted in an ATP-dependent activation, which was approximately 50% of that of hIK1. These results demonstrate that amino acids Arg(355)-Ala(413) within the C terminus of hIK1 confer sensitivity to ATP. Finally, we demonstrate that the ATP-dependent phosphorylation of hIK1 or an associated protein is independent of Ca(2+).

Structure of the gating domain of a Ca2+-activated K+ channel complexed with Ca2+/calmodulin.

Small-conductance Ca2+-activated K+ channels (SK channels) are independent of voltage and gated solely by intracellular Ca2+. These membrane channels are heteromeric complexes that comprise pore-forming alpha-subunits and the Ca2+-binding protein calmodulin (CaM). CaM binds to the SK channel through the CaM-binding domain (CaMBD), which is located in an intracellular region of the alpha-subunit immediately carboxy-terminal to the pore. Channel opening is triggered when Ca2+ binds the EF hands in the N-lobe of CaM. Here we report the 1.60 A crystal structure of the SK channel CaMBD/Ca2+/CaM complex. The CaMBD forms an elongated dimer with a CaM molecule bound at each end; each CaM wraps around three alpha-helices, two from one CaMBD subunit and one from the other. As only the CaM N-lobe has bound Ca2+, the structure provides a view of both calcium-dependent and -independent CaM/protein interactions. Together with biochemical data, the structure suggests a possible gating mechanism for the SK channel.

Structure and complex transcription pattern of the mouse SK1 K(Ca) channel gene, KCNN1.

Small conductance calcium-gated K(+) channels (SK channels) are encoded by the three SK genes, SK1, SK2, and SK3. These channels likely contribute to slow synaptic afterhyperpolarizations of apamin-sensitive and apamin-insensitive types. SK channels are also widely expressed outside the nervous system. The mouse SK1 gene comprises at least 12 exons extending across 19.8 kb of genomic DNA. This gene encodes a complex pattern of alternatively spliced SK1 transcripts widely expressed among mouse tissues. These transcripts exhibit at least four distinct 5'-nucleotide sequence variants encoding at least two N-terminal amino acid sequences. Optional inclusion of exons 7 and 9, together with two alternate splice donor sites in exon 8, yields transcripts encoding eight variant C-terminal amino acid sequences for SK1. These include an altered putative S6 transmembrane span, modification of the C-terminal cytoplasmic domain binding site for calmodulin, and generation of two alternate predicted binding sites for PDZ domain-containing proteins. 20 of the 32 predicted mouse SK1 transcripts are expressed in brain at levels sufficient to allow consistent detection, and encode 16 SK1 polypeptide variants. Only four of these 16 polypeptides preserve the ability to bind calmodulin in a Ca(2+)-independent manner. Mouse SK1 also exhibits novel, strain-specific, length polymorphism of a polyglutamate repeat in the N-terminal cytoplasmic domain. The evolutionary conservation of this complex transcription pattern suggests a possible role in the tuning of SK1 channel function.

Control of electrical activity in central neurons by modulating the gating of small conductance Ca2+-activated K+ channels.

In most central neurons, action potentials are followed by an afterhyperpolarization (AHP) that controls firing pattern and excitability. The medium and slow components of the AHP have been ascribed to the activation of small conductance Ca(2+)-activated potassium (SK) channels. Cloned SK channels are heteromeric complexes of SK alpha-subunits and calmodulin. The channels are activated by Ca(2+) binding to calmodulin that induces conformational changes resulting in channel opening, and channel deactivation is the reverse process brought about by dissociation of Ca(2+) from calmodulin. Here we show that SK channel gating is effectively modulated by 1-ethyl-2-benzimidazolinone (EBIO). Application of EBIO to cloned SK channels shifts the Ca(2+) concentration-response relation into the lower nanomolar range and slows channel deactivation by almost 10-fold. In hippocampal CA1 neurons, EBIO increased both the medium and slow AHP, strongly reducing electrical activity. Moreover, EBIO suppressed the hyperexcitability induced by low Mg(2+) in cultured cortical neurons. These results underscore the importance of SK channels for shaping the electrical response patterns of central neurons and suggest that modulating SK channel gating is a potent mechanism for controlling excitability in the central nervous system.

Acid-sensing ion channel 3 matches the acid-gated current in cardiac ischemia-sensing neurons.

Cardiac afferents are sensory neurons that mediate angina, pain that occurs when the heart receives insufficient blood supply for its metabolic demand (ischemia). These neurons display enormous acid-evoked depolarizing currents, and they fire action potentials in response to extracellular acidification that accompanies myocardial ischemia. Here we show that acid-sensing ion channel 3 (ASIC3), but no other known acid-sensing ion channel, reproduces the functional features of the channel that underlies the large acid-evoked current in cardiac afferents. ASIC3 and the native channel are both especially sensitive to pH, interact similarly with Ca(2+), and gate rapidly between closed, open, and desensitized states. Particularly important is the ability of ASIC3 and the native channel to open at pH 7, a value reached in the first few minutes of a heart attack. The steep activation curve suggests that the channel opens when four protons bind. We propose that ASIC3, a member of the degenerin channel (of Caenorhabditis elegans)/epithelial sodium channel family of ion channels, is the sensor of myocardial acidity that triggers cardiac pain, and that it might be a useful pharmaceutical target for treating angina.

ATP-dependent activation of the intermediate conductance, Ca2+-activated K+ channel, hIK1, is conferred by a C-terminal domain.

We previously demonstrated that hIK1 is activated directly by ATP in excised, inside-out patches in a protein kinase A inhibitor 5-24 dependent manner, suggesting a role for phosphorylation in the regulation of this Ca(2+)-dependent channel. However, mutation of the single consensus cAMP-dependent protein kinase phosphorylation site (S334A) failed to modify the response of hIK1 to ATP (Gerlach, A. C., Gangopadhyay, N. N., and Devor, D. C. (2000) J. Biol. Chem. 275, 585-598). Here we demonstrate that ATP does not similarly activate the highly homologous Ca(2+)-dependent K(+) channels, hSK1, rSK2, and rSK3. To define the region of hIK1 responsible for the ATP-dependent regulation, we generated a series of hIK1 truncations and hIK1/rSK2 chimeras. ATP did not activate a chimera containing the N terminus plus S1-S4 from hIK1. In contrast, ATP activated a chimera containing the hIK1 C-terminal amino acids His(299)-Lys(427). Furthermore, truncation of hIK1 at Leu(414) resulted in an ATP-dependent channel, whereas larger truncations of hIK1 failed to express. Additional hIK1/rSK2 chimeras defined the minimal region of hIK1 required to confer complete ATP sensitivity as including amino acids Arg(355)-Ala(413). An alanine scan of all non-conserved serines and threonines within this region failed to alter the response of hIK1 to ATP, suggesting that hIK1 itself is not directly phosphorylated. Additionally, substitution of amino acids Arg(355)-Met(368) of hIK1 into the corresponding region of rSK2 resulted in an ATP-dependent activation, which was approximately 50% of that of hIK1. These results demonstrate that amino acids Arg(355)-Ala(413) within the C terminus of hIK1 confer sensitivity to ATP. Finally, we demonstrate that the ATP-dependent phosphorylation of hIK1 or an associated protein is independent of Ca(2+).

Respiration and parturition affected by conditional overexpression of the Ca2+-activated K+ channel subunit, SK3.

In excitable cells, small-conductance Ca2+-activated potassium channels (SK channels) are responsible for the slow after-hyperpolarization that often follows an action potential. Three SK channel subunits have been molecularly characterized. The SK3 gene was targeted by homologous recombination for the insertion of a gene switch that permitted experimental regulation of SK3 expression while retaining normal SK3 promoter function. An absence of SK3 did not present overt phenotypic consequences. However, SK3 overexpression induced abnormal respiratory responses to hypoxia and compromised parturition. Both conditions were corrected by silencing the gene. The results implicate SK3 channels as potential therapeutic targets for disorders such as sleep apnea or sudden infant death syndrome and for regulating uterine contractions during labor.

The murine Bis1 seizure gene and the Kcnab2 gene encoding the beta2-subunit of the K+ channel are different.

We tested the hypothesis that Bis1, a gene involved in seizure regulation in mice which has been localized to the distal part of chromosome 4, was the same as the gene Kcnab2, encoding the beta2-subunit for voltage-dependent K+ channels. Two facts suggested this hypothesis: Kcnab2 is located in the 3.1-cM confidence interval containing Bis1 and many studies have shown an involvement of K+ channels in the genesis of seizures. DNA sequence analysis of the coding sequence for Kcnab2 from JE/Le mice revealed no structural alterations which might affect Kcnab2 function. However, several nucleotide changes were observed.

Inhibition of the human intermediate conductance Ca(2+)-activated K(+) channel, hIK1, by volatile anesthetics.

Ca(2+)-activated K(+) channels (K(Ca)) regulate a wide variety of cellular functions by coupling intracellular Ca(2+) concentration to membrane potential. There are three major groups of K(Ca) classified by their unit conductances: large (BK), intermediate (IK), and small (SK) conductance of channels. BK channel is gated by combined influences of Ca(2+) and voltage, while IK and SK channels are gated solely by Ca(2+). Volatile anesthetics inhibit BK channel activity by interfering with the Ca(2+) gating mechanism. However, the effects of anesthetics on IK and SK channels are unknown. Using cloned IK and SK channels, hIK1 and hSK1-3, respectively, we found that the currents of hIK1 were inhibited rapidly and reversibly by volatile anesthetics, whereas those of SK channels were not affected. The IC(50) values of the volatile anesthetics, halothane, sevoflurane, enflurane, and isoflurane for hIK1 inhibition were 0.69, 0.42, 1.01 and 1.03 mM, respectively, and were in the clinically used concentration range. In contrast to BK channel, halothane inhibition of hIK1 currents was independent of Ca(2+) concentration, suggesting that Ca(2+) gating mechanism is not involved. These results demonstrate that volatile anesthetics, such as halothane, enflurane, isoflurane, and sevoflurane, affect BK, IK, and SK channels in distinct ways.

SK2 encodes the apamin-sensitive Ca(2+)-activated K(+) channels in the human leukemic T cell line, Jurkat.

T cells express two different types of voltage-independent Ca(2+)-activated K(+) channels with small (SK) and intermediate (IK) conductance that serve important roles in the activation of T lymphocytes. In contrast to the IK channels from T lymphocytes which are upregulated upon mitogen stimulation, SK channels of Jurkat T cells, a human leukemic T cell line, are constitutively expressed even in the absence of mitogenic stimulation. We have used patch-clamp recordings from transfected or injected mammalian cells to show that the cloned SK2 channel demonstrates the biophysical and pharmacological properties of the majority of K(Ca) channels in Jurkat T cells. The cloned and native channels are voltage-independent, Ca(2+)-activated, apamin-sensitive, show an equivalent voltage-dependent Ba(2+) block and possess a similar ion selectivity. In addition, we used the polymerase chain reaction to demonstrate the presence of SK2 mRNA in Jurkat T cells, whereas SK3 transcripts encoding the other cloned apamin-sensitive SK channel were not detected. These data suggest that the voltage-independent apamin-sensitive K(Ca) channel in Jurkat T cells represents the recently cloned SK2 channel.

Gene structure and chromosome mapping of the human small-conductance calcium-activated potassium channel SK1 gene (KCNN1).

Small-conductance, calcium-activated potassium channels contribute to the afterhyperpolarization in central neurons and other cell types. Because these channels regulate neuronal excitability, defects in their genes could cause excitability disorders. The human cDNA encoding one such channel, SK1 (KCNN1), was recently cloned. Here we describe the gene structure of KCNN1 and its localization by radiation hybrid mapping to chromosome 19p13.1.

Gating properties of single SK channels in hippocampal CA1 pyramidal neurons.

The activation of small-conductance calcium-activated potassium channels (SK) has a profound effect on membrane excitability. In hippocampal pyramidal neurons, SK channel activation by Ca2+ entry from a preceding burst of action potentials generates the slow afterhyperpolarization (AHP). Stimulation of a number of receptor types suppresses the slow AHP, inhibiting spike frequency adaptation and causing these neurons to fire tonically. Little is known of the gating properties of native SK channels in CNS neurons. By using excised inside-out patches, a small-amplitude channel has been resolved that was half-activated by approximately 0.6 microM Ca2+ in a voltage-independent manner. The channel possessed a slope conductance of 10 pS and exhibited nonstationary gating. These properties are in accord with those of cloned SK channels. The measured Ca2+ sensitivity of hippocampal SK channels suggests that the slow AHP is generated by activation of SK channels from a local rise of intracellular Ca2+.