Hans Guenther Knaus scite author profile

Malfunctions of potassium channels are increasingly implicated as causes of neurological disorders. However, the functional roles of the large-conductance voltage-and Ca 2؉ -activated K ؉ channel (BK channel), a unique calcium, and voltage-activated potassium channel type have remained elusive. Here we report that mice lacking BK channels (BK ؊/؊ ) show cerebellar dysfunction in the form of abnormal conditioned eye-blink reflex, abnormal locomotion and pronounced deficiency in motor coordination, which are likely consequences of cerebellar learning deficiency. At the cellular level, the BK ؊/؊ mice showed a dramatic reduction in spontaneous activity of the BK ؊/؊ cerebellar Purkinje neurons, which generate the sole output of the cerebellar cortex and, in addition, enhanced short-term depression at the only output synapses of the cerebellar cortex, in the deep cerebellar nuclei. The impairing cellular effects caused by the lack of postsynaptic BK channels were found to be due to depolarization-induced inactivation of the action potential mechanism. These results identify previously unknown roles of potassium channels in mammalian cerebellar function and motor control. In addition, they provide a previously undescribed animal model of cerebellar ataxia. P otassium channels are the largest and most diverse class of ion channels underlying electrical signaling in the brain (1). By causing highly regulated, time-dependent, and localized polarization of the cell membrane, the opening of K ϩ channels mediates feedback control of excitability in a variety of cell types and conditions (1). Consequently, K ϩ channel dysfunctions can cause a range of neurological disorders (2-6), and drugs that target K ϩ channels hold promise for a variety of clinical applications (7).Among the wide range of voltage-and calcium-gated K ϩ channel types, one stands out as unique: the large-conductance voltage-and Ca 2ϩ -activated K ϩ channel (BK channel, also termed Slo or Maxi-K) differs from all other K ϩ channels in that it can be activated by both intracellular Ca 2ϩ ions and membrane depolarization (8). These channels are widely expressed in central and peripheral neurons, as well as in other tissues (9), and are regarded as a promising drug target (10). However, the functions of the BK channels in vivo have not previously been directly tested in any vertebrate species. We therefore decided to examine the functions of these channels by inactivating the gene encoding the pore-forming channel protein. MethodsA complete description of the methods is given in Supporting Methods, which is published as supporting information on the PNAS web site.Generation of BK Channel ␣ Subunit-Deficient Mice. In the targeting vector (Fig. 5, which is published as supporting information on the PNAS web site), the pore exon was flanked by a single loxP site and a floxed neo͞tk cassette. Correctly targeted embryonic stem cells were injected into C57BL͞6 blastocysts and resulting chimeric mice mated with C57BL͞6. Homozygous BK-deficient mice (F 2 generation) ...

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Presynaptic Ca²⁺-Activated K⁺Channels in Glutamatergic Hippocampal Terminals and Their Role in Spike Repolarization and Regulation of Transmitter Release

Shao

Chavoshy³

et al. 2001

J. Neurosci.

306

303

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Large-conductance Ca 2ϩ -activated K ϩ channels (BK, also called Maxi-K or Slo channels) are widespread in the vertebrate nervous system, but their functional roles in synaptic transmission in the mammalian brain are largely unknown. By combining electrophysiology and immunogold cytochemistry, we demonstrate the existence of functional BK channels in presynaptic terminals in the hippocampus and compare their functional roles in somata and terminals of CA3 pyramidal cells. Doublelabeling immunogold analysis with BK channel and glutamate receptor antibodies indicated that BK channels are targeted to the presynaptic membrane facing the synaptic cleft in terminals of Schaffer collaterals in stratum radiatum. Whole-cell, intracellular, and field-potential recordings from CA1 pyramidal cells showed that the presynaptic BK channels are activated by calcium influx and can contribute to repolarization of the presynaptic action potential (AP) and negative feedback control of Ca 2ϩ influx and transmitter release. This was observed in the presence of 4-aminopyridine (4-AP, 40-100 M), which broadened the presynaptic compound action potential. In contrast, the presynaptic BK channels did not contribute significantly to regulation of action potentials or transmitter release under basal experimental conditions, i.e., without 4-AP, even at high stimulation frequencies. This is unlike the situation in the parent cell bodies (CA3 pyramidal cells), where BK channels contribute strongly to action potential repolarization. These results indicate that the functional role of BK channels depends on their subcellular localization.

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Distribution of high-conductance Ca(2+)-activated K+ channels in rat brain: targeting to axons and nerve terminals

Knaus¹,

Schwarzer²,

Koch³

et al. 1996

J. Neurosci.

297

282

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Tissue expression and distribution of the high-conductance Ca(2+)-activated K+ channel Slo was investigated in rat brain by immunocytochemistry, in situ hybridization, and radioligand binding using the novel high-affinity (Kd 22 pM) ligand [3H]iberiotoxin-D19C ([3H]IbTX-D19C), which is an analog of the selective maxi-K peptidyl blocker IbTX. A sequence-directed antibody directed against Slo revealed the expression of a 125 kDa polypeptide in rat brain by Western blotting and precipitated the specifically bound [3H]IbTX-D19C in solubilized brain membranes. Slo immunoreactivity was highly concentrated in terminal areas of prominent fiber tracts: the substantia nigra pars reticulata, globus pallidus, olfactory system, interpeduncular nucleus, hippocampal formation including mossy fibers and perforant path terminals, medial forebrain bundle and pyramidal tract, as well as cerebellar Purkinje cells. In situ hybridization indicated high levels of Slo mRNA in the neocortex, olfactory system, habenula, striatum, granule and pyramidal cell layer of the hippocampus, and Purkinje cells. The distribution of Slo protein was confirmed in microdissected brain areas by Western blotting and radioligand-binding studies. The latter studies also established the pharmacological profile of neuronal Slo channels. The expression pattern of Slo is consistent with its targeting into a presynaptic compartment, which implies an important role in neural transmission.

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High-conductance calcium-activated potassium channels; Structure, pharmacology, and function

Kaczorowski

Knaus

Leonard

et al. 1996

J Bioenerg Biomembr

271

214

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High-conductance calcium-activated potassium (maxi-K) channels comprise a specialized family of K+ channels. They are unique in their dual requirement for depolarization and Ca2+ binding for transition to the open, or conducting, state. Ion conduction through maxi-K channels is blocked by a family of venom-derived peptides, such as charybdotoxin and iberiotoxin. These peptides have been used to study function and structure of maxi-K channels, to identify novel channel modulators, and to follow the purification of functional maxi-K channels from smooth muscle. The channel consists of two dissimilar subunits, alpha and beta. The alpha subunit is a member of the slo Ca(2+)-activated K+ channel gene family and forms the ion conduction pore. The beta subunit is a structurally unique, membrane-spanning protein that contributes to channel gating and pharmacology. Potent, selective maxi-K channel effectors (both agonists and blockers) of low molecular weight have been identified from natural product sources. These agents, together with peptidyl inhibitors and site-directed antibodies raised against alpha and beta subunit sequences, can be used to anatomically map maxi-K channel expression, and to study the physiologic role of maxi-K channels in various tissues. One goal of such investigations is to determine whether maxi-K channels represent novel therapeutic targets.

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