不同温度条件对下丘脑神经元K+单离子通道簇状开放的影响

目的：探讨温度对下丘脑神经元电压依赖性K^ 单离子通道（Kv）簇状开放（Burst opening）的影响。方法：采用膜片钳细胞贴附式技术观察和记录32℃、37℃和39℃时下丘脑神经元Kv的活动。结果：温度升高,单位时间内记录到的Burst开放明显增多,平均开放间期变长。当温度从32℃升至39℃,B1从1．5ms升至8．1ms,B2从6．6ms升至83．2ms,Burst内部开放数目也由1－2个升至8个,从以简单Burst开放（SB）为主转变成以复杂Burst开放（CB）占优势。结论：温度升高,下丘脑神经元上IK通道更多地处于活动状态,这可能有利于下丘脑神经元对体温变化的调节。     

Tethering chemistry and K+ channels

Voltage-gated K(+) channels are dynamic macromolecular machines that open and close in response to changes in membrane potential. These multisubunit membrane-embedded proteins are responsible for governing neuronal excitability, maintaining cardiac rhythmicity, and regulating epithelial electrolyte homeostasis. High resolution crystal structures have provided snapshots of K(+) channels caught in different states with incriminating molecular detail. Nonetheless, the connection between these static images and the specific trajectories of K(+) channel movements is still being resolved by biochemical experimentation. Electrophysiological recordings in the presence of chemical modifying reagents have been a staple in ion channel structure/function studies during both the pre- and post-crystal structure eras. Small molecule tethering agents (chemoselective electrophiles linked to ligands) have proven to be particularly useful tools for defining the architecture and motions of K(+) channels. This Minireview examines the synthesis and utilization of chemical tethering agents to probe and manipulate the assembly, structure, function, and molecular movements of voltage-gated K(+) channel protein complexes.     

The effect of ATP-sensitive K+ channels on the electrical burst activity and insulin secretion in pancreatic beta-cells.

In recent years, the electrical burst activity of the insulin releasing pancreatic beta-cells has attracted many experimentalists and theoreticians, largely because of its functional importance, but also because of the nonlinear nature of the burst activity. The ATP-sensitive K+ channels are believed to play an important role in electrical activity and insulin release. In this paper, we show by computer simulation how ATP and antidiabetic drugs can lengthen the plateau fraction of bursting and how these chemicals can increase the intracellular Ca2+ level in the pancreatic beta-cell.     

Dilated and defunct K channels in the absence of K+

Potassium ions are vital for maintaining functionality of K channels. In their absence, many K channel types enter a long-lasting defunct condition characterized by absence of conductance and drastic changes in gating current. We show that channels pass through a dilated condition with altered selectivity as they are becoming defunct. To characterize these abnormalities we examined gating and ionic currents generated by Shaker IR and by three nonconducting mutants, W434F, D447N, and Y445A, in 0 K+. On entering the dilated condition, Shaker IR becomes permeable to Na+ and tetramethylammonium-positive (TMA+), signaling deformation of the selectivity filter. When dilated, nearly normal closing is possible at -140 mV. At -80 mV, however, closing is very slow and channels stray from the dilated into the defunct condition. Restoration from defunct to dilated condition requires tens of seconds at 0 mV and can occur in the absence of K+. W434F and D447N are similar to Shaker IR, showing Na+ and TMA+ permeability when dilated. The defunct gating currents are similar in Shaker IR and these two mutants and are reminiscent of the early transitions of normal gating. Y445A does not become defunct and shows Na+ but not TMA+ permeability on K+ removal.     

Na+ and K+ channels: history and structure

In this perspective, we discuss the physiological roles of Na and K channels, emphasizing the importance of the K channel for cellular homeostasis in animal cells and of Na and K channels for cellular signaling. We consider the structural basis of Na and K channel gating in light of recent structural and electrophysiological findings.     

Heteromeric K+ channels in plants

Voltage-gated potassium channels of plants are multimeric proteins built of four α-subunits. In the model plant Arabidopsis thaliana , nine genes coding for K⁺ channel α-subunits have been identified. When co-expressed in heterologous expression systems, most of them display the ability to form heteromeric K⁺ channels. Till now it was not clear whether plants use this potential of heteromerization to increase the functional diversity of potassium channels. Here, we designed an experimental approach employing different transgenic plant lines that allowed us to prove the existence of heteromeric K⁺ channels in plants. The chosen strategy might also be useful for investigating the activity and function of other multimeric channel proteins like, for instance, cyclic-nucleotide gated channels, tandem-pore K⁺ channels and glutamate receptor channels.     

Voltage-dependent K+ currents and underlying single K+ channels in pheochromocytoma cells

Properties of the whole-cell K+ currents and voltage-dependent activation and inactivation properties of single K+ channels in clonal pheochromocytoma (PC-12) cells were studied using the patch-clamp recording technique. Depolarizing pulses elicited slowly inactivating whole-cell K+ currents, which were blocked by external application of tetraethylammonium+, 4-aminopyridine, and quinidine. The amplitudes and time courses of these K+ currents were largely independent of the prepulse voltage. Although pharmacological agents and manipulation of the voltage-clamp pulse protocol failed to reveal any additional separable whole-cell currents in a majority of the cells examined, single-channel recordings showed that, in addition to the large Ca++-dependent K+ channels described previously in many other preparations, PC-12 cells had at least four distinct types of K+ channels activated by depolarization. These four types of K+ channels differed in the open-channel current-voltage relation, time course of activation and inactivation, and voltage dependence of activation and inactivation. These K+ channels were designated the Kw, Kz, Ky, and Kx channels. The typical chord conductances of these channels were 18, 12, 7, and 7 pS in the excised configuration using Na+-free saline solutions. These four types of K+ channels opened in the presence of low concentrations of internal Ca++ (1 nM). Their voltage-dependent gating properties can account for the properties of the whole-cell K+ currents in PC-12 cells.     

Calcium-activated K+ channels increase cell proliferation independent of K+ conductance

The intermediate-conductance calcium-activated potassium channel (IK1) promotes cell proliferation of numerous cell types including endothelial cells, T lymphocytes, and several cancer cell lines. The mechanism underlying IK1-mediated cell proliferation was examined in human embryonic kidney 293 (HEK293) cells expressing recombinant human IK1 (hIK1) channels. Inhibition of hIK1 with TRAM-34 reduced cell proliferation, while expression of hIK1 in HEK293 cells increased proliferation. When HEK293 cells were transfected with a mutant (GYG/AAA) hIK1 channel, which neither conducts K(+) ions nor promotes Ca(2+) entry, proliferation was increased relative to mock-transfected cells. Furthermore, when HEK293 cells were transfected with a trafficking mutant (L18A/L25A) hIK1 channel, proliferation was also increased relative to control cells. The lack of functional activity of hIK1 mutants at the cell membrane was confirmed by a combination of whole cell patch-clamp electrophysiology and fura-2 imaging to assess store-operated Ca(2+) entry and cell surface immunoprecipitation assays. Moreover, in cells expressing hIK1, inhibition of ERK1/2 and JNK kinases, but not of p38 MAP kinase, reduced cell proliferation. We conclude that functional K(+) efflux at the plasma membrane and the consequent hyperpolarization and enhanced Ca(2+) entry are not necessary for hIK1-induced HEK293 cell proliferation. Rather, our data suggest that hIK1-induced proliferation occurs by a direct interaction with ERK1/2 and JNK signaling pathways.     

Quinine inhibits Ca2+-independent K+ channels whereas tetraethylammonium inhibits Ca2+-activated K+ channels in insulin-secreting cells

The effects of quinine and tetraethylammonium (TEA) on single-channel K+ currents recorded from excised membrane patches of the insulin-secreting cell line RINm5F were investigated. When 100 microM quinine was applied to the external membrane surface K+ current flow through inward rectifier channels was abolished, while a separate voltage-activated high-conductance K+ channel was not significantly affected. On the other hand, 2 mM TEA abolished current flow through voltage-activated high-conductance K+ channels without influencing the inward rectifier K+ channel. Quinine is therefore not a specific inhibitor of Ca2+-activated K+ channels, but instead a good blocker of the Ca2+-independent K+ inward rectifier channel whereas TEA specifically inhibits the high-conductance voltage-activated K+ channel which is also Ca2+-activated.     

钾通道家族新成员:双孔道钾通道的研究进展

双孔道钾通道（K2p）是钾通道超家族的新成员。它广泛分布于兴奋和非兴奋组织中,具有4次跨膜片段、两个孔道结构域的结构特征,目前主要分为：TWIK、多不饱和脂肪酸激活的钾通道、TASK和KCNK沉寂亚单位四类。K2p具有瞬间激活和不失活,以及对TEA、4－AP等经典钾通道阻断剂不敏感的电生理特性,参与调节背景钾电流或钾漏流。许多机械性和化学性刺激如细胞牵拉、pH值的变化、第二信使、花生四烯酸和吸入麻醉剂等均参与调控K2p通道。     

Calcium-activated K+ channels: Metabolic regulation

Calcium-activated potassium (K_Ca) channels are highly modulated by a large spectrum of metabolites. Neurotransmitters, hormones, lipids, and nucleotides are capable of activating and/or inhibiting K_Ca channels. Studies from the last few years have shown that metabolites modulate the activity of K_Ca channels via: (1) a change in the affinity of the channel for Ca²⁺ (K_1/2 is modified), (2) a parallel shift in the voltage axis of the acitvation curves, or (3) a change in the slope (effective valence) of the voltage dependence curve. The shift of the voltage dependence curve can be a direct consequence of the change in the affinity for Ca²⁺. Recently, the mechanistic steps involved in the modulation of K_Ca channels are being uncovered. Some interactions may be direct on K_Ca channels and others may be mediated via G-proteins, second messengers, or phosphorylation. The information given in this review highlights the possibility that K_Ca channels can be activated or inhibited by metabolites without a change in the intracellular Ca²⁺ concentration.     

Molecular properties of voltage-gated K+ channels

Subfamilies of voltage-activated K⁺ channels (Kv1-4) contribute to controlling neuron excitability and the underlying functional parameters. Genes encoding the multiple subunits from each of these protein groups have been cloned, expressed and the resultant distinct K⁺ currents characterized. The predicted amino acid sequences showed that each subunit contains six putative membrane-spanning -helical segments (S1-6), with one (S4) being deemed responsible for the channels' voltage sensing. Additionally, there is an H5 region, of incompletely defined structure, that traverses the membrane and forms the ion pore; residues therein responsible for K⁺ selectivity have been identified. Susceptibility of certain K⁺ currents produced by the Shaker-related subfamily (Kv1) to inhibition by -dendrotoxin has allowed purification of authentic K⁺ channels from mammalian brain. These are large (M_r 400 kD), octomeric sialoglycoproteins composed of and subunits in a stoichiometry of ()₄()₄, with subtypes being created by combinations of subunit isoforms. Subsequent cloning of the genes for ₁, ₂ and ₃ subunits revealed novel sequences for these hydrophilic proteins that are postulated to be associated with the subunits on the inner side of the membrane. Coexpression of ₁ and Kv1.4 subunits demonstrated that this auxiliary protein accelerates the inactivation of the K⁺ current, a striking effect mediated by an N-terminal moiety. Models are presented that indicate the functional domains pinpointed in the channel proteins.     

Tyrosine-rich conopeptides affect voltage-gated K+ channels

Two venom peptides, CPY-Pl1 (EU000528) and CPY-Fe1 (EU000529), characterized from the vermivorous marine snails Conus planorbis and Conus ferrugineus, define a new class of conopeptides, the conopeptide Y (CPY) family. The peptides have no disulfide cross-links and are 30 amino acids long; the high content of tyrosine is unprecedented for any native gene product. The CPY peptides were chemically synthesized and shown to be biologically active upon injection into both mice and Caenorhabditis elegans; activity on mammalian Kv1 channel isoforms was demonstrated using an oocyte heterologous expression system, and selectivity for Kv1.6 was found. NMR spectroscopy revealed that the peptides were unstructured in aqueous solution; however, a helical region including residues 12-18 for one peptide, CPY-Pl1, formed in trifluoroethanol buffer. Clones obtained from cDNA of both species encoded prepropeptide precursors that shared a unique signal sequence, indicating that these peptides are encoded by a novel gene family. This is the first report of tyrosine-rich bioactive peptides in Conus venom.     

Apoptotic surface delivery of K+ channels

Apoptosis in cortical neurons requires efflux of cytoplasmic potassium mediated by a surge in Kv2.1 channel activity. Pharmacological blockade or molecular disruption of these channels in neurons prevents apoptotic cell death, while ectopic expression of Kv2.1 channels promotes apoptosis in non-neuronal cells. Here, we use a cysteine-containing mutant of Kv2.1 and a thiol-reactive covalent inhibitor to demonstrate that the increase in K+ current during apoptosis is due to de novo insertion of functional channels into the plasma membrane. Biotinylation experiments confirmed the delivery of additional Kv2.1 protein to the cell surface following an apoptotic stimulus. Finally, expression of botulinum neurotoxins that cleave syntaxin and synaptosome-associated protein of 25 kDa (SNAP-25) blocked upregulation of surface Kv2.1 channels in cortical neurons, suggesting that target soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins support proapoptotic delivery of K+ channels. These data indicate that trafficking of Kv2.1 channels to the plasma membrane causes the apoptotic surge in K+ current.