Mutations in the S4 region isolate the final voltage-dependent cooperative step in potassium channel activation

Charged residues in the S4 transmembrane segment play a key role in determining the sensitivity of voltage-gated ion channels to changes in voltage across the cell membrane. However, cooperative interactions between subunits also affect the voltage dependence of channel opening, and these interactions can be altered by making substitutions at uncharged residues in the S4 region. We have studied the activation of two mutant Shaker channels that have different S4 amino acid sequences, ILT (V369I, I372L, and S376T) and Shaw S4 (the S4 of Drosophila Shaw substituted into Shaker), and yet have very similar ionic current properties. Both mutations affect cooperativity, making a cooperative transition in the activation pathway rate limiting and shifting it to very positive voltages, but analysis of gating and ionic current recordings reveals that the ILT and Shaw S4 mutant channels have different activation pathways. Analysis of gating currents suggests that the dominant effect of the ILT mutation is to make the final cooperative transition to the open state of the channel rate limiting in an activation pathway that otherwise resembles that of Shaker. The charge movement associated with the final gating transition in ILT activation can be measured as an isolated component of charge movement in the voltage range of channel opening and accounts for 13% ( approximately 1.8 e0) of the total charge moved in the ILT activation pathway. The remainder of the ILT gating charge (87%) moves at negative voltages, where channels do not open, and confirms the presence of Shaker-like conformational changes between closed states in the activation pathway. In contrast to ILT, the activation pathway of Shaw S4 seems to involve a single cooperative charge-moving step between a closed and an open state. We cannot detect any voltage-dependent transitions between closed states for Shaw S4. Restoring basic residues that are missing in Shaw S4 (R1, R2, and K7) rescues charge movement between closed states in the activation pathway, but does not alter the voltage dependence of the rate-limiting transition in activation.     

慢性低氧对豚鼠右室心肌细胞钙、钾电流的影响

采用全细胞膜片箝技术,分别记录并比较正常对照组与慢性低氧组豚鼠单个右室心肌细胞的膜电容、L型钙电流和延迟整流钾电流峰值和电流-电压关系曲线,以探讨慢性低氧对豚鼠右室心肌细胞L型钙电流和延迟整流钾电流的影响。结果表明,上述两组细胞膜电容分别为（155±13．2）pF、（179±14,8）pF,低氧组显著大于正常对照组（P＜0．01）;L型钙电流峰值分别为（1．07±0．21）nA和（0．99±0．17）nA,两组之间无显著差异;在-20mV至＋20mV,慢性低氧组L型钙电流密度较正常对照组显著下降（P＜0．05）。在＋月mV至＋60mV之间,慢性低氧组豚鼠右室心肌细胞延迟整流钾电流幅度均小于正常对照组;在-20mV至＋60mV之间,慢性低氧组豚鼠右室心肌细胞延迟整流钾电流密度明显低于正常对照组。可见慢性低氧能使豚鼠右室心肌细胞膜电容增加,L型钙电流幅度不变,但L型钙电流密度下降;同时慢性低氧降低豚鼠右室心肌细胞延迟整流钾电流幅度和密度。     

利诺吡啶对豚鼠耳蜗外毛细胞和Deiters细胞钾电流的抑制

为探讨KCNQ家族钾通道在耳蜗外毛细胞和Deiters细胞的功能性表达,我们观察并记录了KCNQ家族钾通道阻滞剂利诺吡啶对豚鼠耳蜗单离外毛细胞(outer hair cells,OHCs)和Deiters细胞总钾电流的影响。采用酶孵育加机械分离法分离豚鼠耳蜗单个OHCs和Deiters细胞：运用膜片钳技术,在全细胞模式下记录正常细胞外液中8个外毛细胞和5个Deiters细胞的总钾电流,并观察100μmol／L和200μmol／L利诺吡啶对外毛细胞和Deiters细胞总钾电流的影响。结果观察到,在正常细胞外液中的单离外毛细胞,可记录到四乙基二乙胺敏感的外向性钾电流和静息膜电位附近激活的内向性钾电流(the K^ current activated at negative potential,IKa)两种钾电流,而在单离Deiters细胞中只记录到外向整流性钾电流。在细胞外液中,加入100μmol／L利诺吡啶后,OHCs中的四乙基二乙胺敏感的钾电流峰电流成分被抑制,稳态电流幅值减小,且电流的失活时问常数明显延长;在细胞外液中加入100μmol／L和200μmol／L利诺吡啶后,OHCs的内向性钾电流IKa被完全抑制;而细胞外液中利诺吡啶终浓度为200μmol／L时,Deiters细胞的外向整流性钾电流幅值无明显变化。由此我们推测,KCNQ家族钾通道存在于豚鼠耳蜗外毛细胞,其介导的钾电流是四乙基二乙胺敏感的钾电流的组成部分,并构成全部的IKn,其功能是介导细胞内K^ 外流和防止细胞过度去极化;KCNQ家族钾通道不存在于豚鼠耳蜗Dciters细胞。     

慢性间歇性低氧降低急性缺氧对大鼠肺动脉平滑肌细胞膜上电压门控性钾通道的抑制

为了从离子通道水平上探讨机体低氧适应的离子机制,本实验将雄性 SD 大鼠随机分为常氧对照组和慢性间歇性低氧组[氧浓度(10 ± 0.5) %, 间断缺氧每天 8 h]。用酶解法急性分离单个大鼠肺内动脉平滑肌细胞(pulmonary artery smoothmuscle cells, PASMCs),以全细胞膜片钳技术记录 PASMCs 膜上的电压门控性钾通道 (voltage-gated potassium channel, KV) 电流,观察急性缺氧对慢性间歇性低氧大鼠 PASMCs 的 KV 的影响, 为机体适应低氧能力提供实验依据。结果显示:⑴常氧对照组在电流钳下,急性缺氧可使膜电位明显去极化(由-47.2 ±2.6 mV 去极到 -26.7 ±1.2 mV ); 在电压钳下, 急性缺氧可显著抑制 KV电流( 60 mV 时, KV电流密度从 153.4 ± 9.5 pA/pF降到 70.1 ± 10.6 pA/pF), 峰电流的抑制率为(57.6 ± 3.3) %, 电流-电压关系曲线向右下移。⑵慢性间歇性低氧组KV电流密度随低氧时间延长而逐渐减少(慢性低氧10 d后就有显著性意义),电流- 电压关系曲线逐渐右下移。⑶急性缺氧对慢性间歇性低氧大鼠PASMCs KV电流的抑制作用随慢性间歇性低氧时间延长而逐渐减弱。上述观察结果提示慢性间歇性低氧减弱急性缺氧对 KV 的抑制, 这可能是机体低氧适应的一种重要机制。     

ATP激活鼻咽癌细胞氯电流并减小细胞容积

采用全细胞膜片钳技术和细胞容积测量技术,在低分化鼻咽癌细胞株CNE-2Z上观察ATP 诱导的Cl- 电流的特性及其对细胞容积的影响。细胞外微摩尔水平的ATP 以剂量依赖性的方式激活一个具有弱外向整流特性,没有时间依赖性失活的电流,此电流的反转电位 [(-0.05 ± 0.03) mV]接近Cl- 的平衡电位(-0.9 mV)。用葡萄糖酸置换细胞外液Cl- 后, ATP 激活的电流明显减小并且反转电位发生改变。氯通道抑制剂NPPB (200 μmol/L)可以抑制这一电流 [(81.03 ± 9.3)%] 。此电流亦可被嘌呤受体(P2Y) 拮抗剂反应蓝 2 抑制 [(67.39 ± 5.06)%]。50 μmol/L 的 ATP 使在等渗状态下的细胞容积缩小, 替代和耗竭细胞外、内的Cl- 后, ATP 的这一作用消失。这些结果提示细胞外微摩尔水平的 ATP 可通过兴奋 P2Y 受体激活氯通道而产生与细胞容积调节相关的Cl- 电流。     

Fatty Acids Induce Chloride Permeation in Rat Liver Mitochondria by Activation of the Inner Membrane Anion Channel (IMAC)

The inner membrane of freshly isolated mammalian mitochondria is poorly permeable to Cl(-). Low, nonlytic concentrations (< or =30 microM) of long-chain fatty acids or their branched-chain derivatives increase permeation of Cl(-) as indicated from rapid large-scale swelling of mitochondria suspended in slightly alkaline KCl medium (supplemented with valinomycin). Myristic, palmitic, or 5-doxylstearic acid are powerful inducers of Cl(-) permeation, whereas lauric, phytanic, stearic, or 16-doxylstearic acid stimulate Cl(-) permeation in a lesser extent. Fatty acid-induced Cl(-) permeation across the inner membrane correlates well with the property of nonesterified fatty acids to release endogenous Mg(2+) from mitochondria. Myristic acid stimulates anion permeation in a selective manner, similar as was described for A23187, an activator of the inner membrane anion channel (IMAC). Myristic acid-induced Cl(-) permeation is blocked by low concentrations of tributyltin chloride (IC(50) approximately 1.5 nmol/mg protein). Moreover, myristic acid activates a transmembrane ion current in patch-clamped mitoplasts (mitochondria with the outer membrane removed) exposed to alkaline KCl medium. This current is best ascribed to the opening of an ion channel with a single-channel conductance of 108 pS. We propose that long-chain fatty acids can activate IMAC by withdrawal of Mg(2+) from intrinsic binding sites.     

CoCl2预处理对大鼠海马神经元急性低氧后Na+、K+电流的影响

目的：观察氯化钴(COCl2)预处理对急性低氧后海马神经元电压门控性Na^ 、K^ 电流的影响。方法：原代培养大鼠海马神经元,分为COCl2预处理和非处理组,采用膜片钳全细胞记录技术,检测急性低氧后海马神经元钠电流(INa)、钾电流(Ik)的变化。结果：急性低氧后,海马神经元INa、Ik电流幅度明显降低,INa阈值右移,而经CoCl2预处理的海马神经元INa、Ik电流的降低幅度明显减轻。结论：COCl2预处理减轻急性低氧所致的INa、Ik电流变化,对神经元有明显的保护作用。     

State dependent behavior and the Marginal Value Theorem

The Marginal Value Theorem (MVT) is the dominant paradigm inpredicting patch use and numerous tests support its qualitativepredictions. Quantitative tests under complex foraging situationscould be expected to be more variable in their support becausethe MVT assumes behavior maximizes only net energy-intake rate.However across a survey of 26 studies, foragers rather consistently"erred" in staying too long in patches. Such a consistent directionto the errors suggests that the simplifying assumptions ofthe MVT introduce a systematic bias rather than just imprecision. Therefore, I simulated patch use as a state-dependent responseto physiological state, travel cost, predation risk, prey densities,and fitness currencies other than net-rate maximization (e.g.,maximizing survival, reproductive investment, or mating opportunities).State-dependent behavior consistently results in longer patchresidence times than predicted by the MVT or another foragingmodel, the minimize µ/g rule, and these rules fail to closely approximate the best behavioral strategy over a widerange of conditions. Because patch residence times increasewith state-dependent behavior, this also predicts mass regulationbelow maximum energy capacities without direct mass-specificcosts. Finally, qualitative behavioral predictions from theMVT about giving-up densities in patches and the effects oftravel costs are often inconsistent with state-dependent behavior.Thus in order to accurately predict patch exploitation patterns,the model highlights the need to: (1) consider predator behavior(sit-and-wait versus actively foraging); (2) identify activitiesthat can occur simultaneously to foraging (i.e., mate searchor parental care); and (3) specify the range of nutritional states likely in foraging animals. Future predictive modelsof patch use should explicitly consider these parameters.     

Mechanosensitive channel of Thermoplasma, the cell wall-less archaea

By using a functional approach of reconstituting detergent-solubilized membrane proteins into liposomes and following their function in patch-clamp experiments, we identified a novel mechanosensitive (MS) channel in the thermophilic cell wall-less archaeon Thermoplasma volcanium. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) of the enriched protein fractions revealed a band of approx 15 kDa comparable to MscL, the bacterial MS channel of large conductance. 20 N-terminal residues determined by protein microsequencing, matched the sequence to an unknown open reading frame in the genome of a related species Thermoplasma acidophilum. The protein encoded by the T. acidophilum gene was cloned and expressed in Escherichia coli and reconstituted into liposomes. When examined for function, the reconstituted protein exhibited properties typical of an MS ion channel: 1) activation by negative pressure applied to the patch-clamp pipet, 2) blockage by gadolinium, and 3) activation by the anionic amphipath trinitrophenol. In analogy to the nomenclature used for bacterial MS channels, the MS channel of T. acidophilum was termed MscTA. Secondary structural analysis indicated that similar to MscL, the T. acidophilum MS protein may have two transmembrane domains, suggesting that MS channels of thermophilic Archaea belong to a family of structurally related MscL-like ion channels with two membrane-spanning regions. When the mscTA gene was expressed in the mscL ⁻ knockout strain and the MscTA protein reconstituted into liposomes, the gating of MscTA was charaterized by very brief openings of variable conductance. In contrast, when the mscTA gene was expressed in the wild-type mscL ⁺ strain of E. coli, the gating properties of the channel resembled MscL. However, the channel had reduced conductance and differed from MscL in its kinetics and in the free energy of activation, suggesting that MscTA and MscL can form functional complexes and/or modulate each other activity. Similar to MscL, MscTA exhibited an increase in activity in liposomes made of phospholipids having shorter acyl chain, suggesting a role of hydrophobic mismatch in the function of prokaryotic MS channels.     

Fine gating properties of channels responsible for persistent sodium current generation in entorhinal cortex neurons

The gating properties of channels responsible for the generation of persistent Na(+) current (I(NaP)) in entorhinal cortex layer II principal neurons were investigated by performing cell-attached, patch-clamp experiments in acutely isolated cells. Voltage-gated Na(+)-channel activity was routinely elicited by applying 500-ms depolarizing test pulses positive to -60 mV from a holding potential of -100 mV. The channel activity underlying I(NaP) consisted of prolonged and frequently delayed bursts during which repetitive openings were separated by short closings. The mean duration of openings within bursts was strongly voltage dependent, and increased by e times per every approximately 12 mV of depolarization. On the other hand, intraburst closed times showed no major voltage dependence. The mean duration of burst events was also relatively voltage insensitive. The analysis of burst-duration frequency distribution returned two major, relatively voltage-independent time constants of approximately 28 and approximately 190 ms. The probability of burst openings to occur also appeared largely voltage independent. Because of the above "persistent" Na(+)-channel properties, the voltage dependence of the conductance underlying whole-cell I(NaP) turned out to be largely the consequence of the pronounced voltage dependence of intraburst open times. On the other hand, some kinetic properties of the macroscopic I(NaP), and in particular the fast and intermediate I(NaP)-decay components observed during step depolarizations, were found to largely reflect mean burst duration of the underlying channel openings. A further I(NaP) decay process, namely slow inactivation, was paralleled instead by a progressive increase of interburst closed times during the application of long-lasting (i.e., 20 s) depolarizing pulses. In addition, long-lasting depolarizations also promoted a channel gating modality characterized by shorter burst durations than normally seen using 500-ms test pulses, with a predominant burst-duration time constant of approximately 5-6 ms. The above data, therefore, provide a detailed picture of the single-channel bases of I(NaP) voltage-dependent and kinetic properties in entorhinal cortex layer II neurons.