拟南芥根皮层细胞质膜内向K+通道电生理特性分析

利用膜片钳技术对模式植物拟南芥根皮层细胞原生质体的内向跨膜钾电流进行了全细胞记录 ,并对内向K⁺通道的特性进行了分析 .结果表明 ,拟南芥根细胞质膜上的内向K⁺通道由超极化膜电位所激活 ;该通道具有较高的K^+/Na⁺选择性 ,可被TEA⁺和Ba^{2 +}等K+通道阻断剂所抑制 ,而且对胞内自由Ca^{2 +}浓度变化不敏感 .这为进一步利用模式植物拟南芥进行植物K⁺吸收机制以及植物抗盐机制的研究奠定了基础 .     

大鼠前脂细胞质膜Na+/H+交换同时参与细胞的增殖和分化

以原代培养的大鼠前脂细胞为模型 ,以 2′ ,7′ bis ( 2 carboxyethyl) 5 ( 6 ) carboxyfluorescein (BCECF)作为检测胞内pH(pHi)的荧光探针 ,测定不同生长因子刺激下胞内pH的变化 ,证明大鼠肾周前脂细胞质膜存在Na⁺/H⁺交换活性 ,胎牛血清(FCS)能快速激活Na⁺/H⁺交换 ,导致pHi升高 (约 0 .2pH单位 ) ,并引起DNA合成 .Ethyl isopropyl amiloride (EIPA)抑制Na⁺/H⁺交换与DNA合成 .在无血清条件下 ,胰岛素不刺激DNA合成但引起细胞分化 ,表现为胞内脂滴积累和 3 磷酸 甘油脱氢酶(G₃ PDH酶 )活性增强 ,同时激活Na⁺/H⁺交换活性导致pHi升高 ;EIPA既抑制胰岛素对Na⁺/H⁺交换的激活 ,也抑制G₃ PDH酶活性增强 .结果证明 :Na⁺/H⁺交换的激活不仅与大鼠前脂细胞增殖相关 ,同时也是细胞分化的早期事件 .     

重复膜片钳法研究MPP+对神经元钙电流作用

细胞膜片钳技术是研究膜离子通道的有效方法.在单个细胞上反复形成多次全细胞构型从而在同一细胞上观察某些药物的长时间作用对于通道膜电流的影响.利用全细胞构型下胞浆与电极内液的连通可以方便地向胞内引入药物.以此法研究MPP⁺多巴胺能神经瘤细胞(MN9D)的毒性作用表明MPP⁺导致细胞电压依赖性钙电流(I_Ca)显著下降;MPP⁺作用1 h以内高去极化电压较低去极化电压诱发的钙电流先受MPP⁺影响而下降; MPP⁺对未分化细胞的钙电流无显著作用(n=3).     

大鼠背根神经节神经元上失活 BK 通道特性的研究

大电导的电压和 Ca²⁺ 激活的 K⁺ 通道 (BK 通道 ) 在哺乳动物的组织中广泛表达,起着多种多样的作用 . 目前只有少数组织中 BK 通道的性质被深入地研究,而且鲜见有失活的 BK 通道 (BK_i) 的报道,尤其是在神经元中 . 发现在大鼠小直径的背根神经节 (DRG) 神经元中,普遍存在失活的 BK 通道 . 失活的 BK 电流成分是 Ca²⁺敏感的,可以被大电导的 BK 通道特异阻断剂 ChTX 所阻断,而且木瓜蛋白酶可以从胞外改变通道失活的特性 .     

TRPM7生理病理学功能及其小分子调节剂的发现

TRPM7（transient receptor potential melastatin 7）通道属于TRPM亚家族，是一种具有离子通道结构域和激酶结构域的双功能跨膜蛋白。作为非选择性阳离子通道，TRPM7可通透Ca²⁺、Mg²⁺、Zn²⁺、Na⁺、K⁺等和其他微量金属离子。TRPM7在人体各组织广泛表达，参与Mg²⁺的稳态调控、细胞增殖、分化、黏附和迁移等生理过程。临床上，TRPM7功能紊乱与神经退行性疾病、中风、癌症等多种疾病关系密切。本文主要综述TRPM7通道在生理、病理及小分子调节剂方面的研究进展，为相关疾病的药物开发提供新的思路。     

植物钙依赖型蛋白激酶激活液泡膜上的阴离子通道

运用膜片钳技术研究植物钙依赖型蛋白激酶(CDPK)对细胞液泡离子通道的作用,发现它明显地激活液泡膜上一种电流方向与慢液泡(SV)通道电流相反的阴离子通道.用CsCl和GluK作通道阻断试验,结果表明它是一种Cl^-通道,单通道电导约为30pS,不同于SV的50～100 pS.对它在细胞信息传导中的作用作了分析.     

川楝素对K+、Ca2+通道活动及细胞内Ca2+浓度的调控

川楝素是我国学者从驱蛔中药中分离、鉴定的一个三萜化合物，已证明具选择地影响神经递质释放，有效地对抗肉毒中毒，促进细胞分化、凋亡，抑制肿瘤增殖，抑制昆虫发育和取食，影响K⁺、Ca²⁺通道活动等多种生物效应. 综述了证明川楝素抑制多种K⁺通道，选择地易化L型Ca²⁺通道和进而升高胞内Ca⁺浓度的研究资料，并对川楝素产生这些生物效应的机制进行了讨论.     

钾通道在培养大鼠海马神经元凋亡性容积减少中的作用

为探讨钾通道参与神经元凋亡的可能机制,在星形孢菌素（STS)诱导的培养海马神经元凋亡模型上,研究了凋亡时神经细胞容积的动态变化及钾通道在其中的作用.实验结果显示,钾通道阻断剂四乙铵或升高细胞外K⁺均能够明显抑制STS诱导的神经元凋亡,并且大电导钙激活钾通道（BK）选择性阻断剂iberiotoxin和paxilline具有同样程度的抗细胞凋亡作用,表明钾通道（可能主要是BK通道）参与了STS诱导的培养海马神经元凋亡.在STS诱导神经元凋亡的早期就出现了细胞容积的显著减少,而钾通道阻断剂或升高细胞外K⁺均可阻断该细胞容积减少.研究结果提示细胞内钾离子的外流可能参与了凋亡性细胞容积减少,这也可能是钾通道介导细胞凋亡的重要机制之一.     

CD38基因敲除的淋巴瘤细胞株构建

摘要 目的：构建Luc⁺CD38^-的Raji细胞株,并进行功能的初步验证,为后期探索淋巴瘤细胞CD38位点免疫逃逸现象奠定基础。方法：通过CRISPR-cas9技术和PiggyBac(PB)转座子系统,对Luc⁺Raji细胞的CD38基因位点进行敲除,构建Luc⁺CD38^-Raji细胞株,使用流式细胞术检测与Luc⁺CD38^-Raji细胞株以1：1的比例共孵育CD19 CAR-T和CD38 CAR-T以及未转导的原始T细胞表面活化因子CD69的表达水平,荧光素酶检测法检测上述几组效应细胞对Luc⁺CD38^-Raji细胞株的杀伤效率。结果：成功构建Luc⁺CD38^-Raji细胞,激活实验结果显示,CD19 CAR-T与CD38 CAR-T均可以被Luc⁺Raji细胞激活。而Luc⁺CD38^-Raji19号单克隆细胞由于缺失CD38的表达,仅能够激活CD19 CAR-T。杀伤实验结果显示,两种CAR-T细胞均能够对Luc⁺Raji细胞进行杀伤,而CD38 CAR-T对Luc⁺CD38^-Raji19号单克隆细胞的杀伤效率与原始的T细胞相似。结论：成功构建了Luc⁺CD38^-Raji细胞株,为后期探索淋巴瘤CD38位点免疫逃逸现象奠定基础。     

太赫兹刺激听神经的测试平台搭建

目的 近年来，用于脑功能调控的神经调控技术蓬勃发展，很多方法已在临床上被推广应用，主要包括电极深部脑刺激、经颅磁刺激、光遗传技术、超声深脑刺激等。但是这些调控技术存在刺激靶点改变灵活性差、空间分辨率不足、需要注射病毒转染等问题。与这些技术相比，太赫兹波调控则能以较高的时空分辨率、无需引入外源基因的方式对神经活动进行干预。激光神经刺激是一种具有较明确靶向性的刺激方法，可以通过调整不同激光参数（激光波长、脉冲能量等）控制引起神经兴奋或者抑制。但是由于该研究方向的实验手段和实验平台的缺乏，相关研究开展较少。方法 针对这个问题，从听觉神经入手，在分子、细胞和在体不同层面为相关领域的研究搭建了不同的测试平台。结果 实验结果表明，这些系统在时间和空间上具有良好的耦合性和靶向性，测得的信号受噪音干扰小。结论 这些系统可以有效测试神经系统对太赫兹刺激的响应并精确控制刺激时间和位置。     

Effect of non-symmetric waveform on conduction block induced by high-frequency (kHz) biphasic stimulation in unmyelinated axon

The effect of a non-symmetric waveform on nerve conduction block induced by high-frequency biphasic stimulation is investigated using a lumped circuit model of the unmyelinated axon based on Hodgkin-Huxley equations. The simulation results reveal that the block threshold monotonically increases with the stimulation frequency for the symmetric stimulation waveform. However, a non-monotonic relationship between block threshold and stimulation frequency is observed when the stimulation waveform is non-symmetric. Constant activation of potassium channels by the high-frequency stimulation results in the increase of block threshold with increasing frequency. The non-symmetric waveform with a positive pulse 0.4–0.8 μs longer than the negative pulse blocks axonal conduction by hyperpolarizing the membrane and causes a decrease in block threshold as the frequency increases above 12–16 kHz. On the other hand, the non-symmetric waveform with a negative pulse 0.4–0.8 μs longer than the positive pulse blocks axonal conduction by depolarizing the membrane and causes a decrease in block threshold as the frequency increases above 40–53 kHz. This simulation study is important for understanding the potential mechanisms underlying the nerve block observed in animal studies, and may also help to design new animal experiments to further improve the nerve block method for clinical applications.     

Analysis of nerve conduction block induced by direct current

The mechanisms of nerve conduction block induced by direct current (DC) were investigated using a lumped circuit model of the myelinated axon based on Frankenhaeuser–Huxley (FH) model. Four types of nerve conduction block were observed including anodal DC block, cathodal DC block, virtual anodal DC block, and virtual cathodal DC block. The concept of activating function was used to explain the blocking locations and relation between these different types of nerve block. Anodal/cathodal DC blocks occurred at the axonal nodes under the block electrode, while virtual anodal/cathodal DC blocks occurred at the nodes several millimeters away from the block electrode. Anodal or virtual anodal DC block was caused by hyperpolarization of the axon membrane resulting in the failure of activating sodium channels by the arriving action potential. Cathodal or virtual cathodal DC block was caused by depolarization of the axon membrane resulting in inactivation of the sodium channel. The threshold of cathodal DC block was lower than anodal DC block in most conditions. The threshold of virtual anodal/cathodal blocks was about three to five times higher than the threshold of anodal/cathodal blocks. The blocking threshold was decreased with an increase of axonal diameter, a decrease of electrode distance to axon, or an increase of temperature. This simulation study, which revealed four possible mechanisms of nerve conduction block in myelinated axons induced by DC current, can guide future animal experiments as well as optimize the design of electrodes to block nerve conduction in neuroprosthetic applications.     

Mechanism of conduction block in amphibian myelinated axon induced by biphasic electrical current at ultra-high frequency

The mechanism of axonal conduction block induced by ultra-high frequency (≥20 kHz) biphasic electrical current was investigated using a lumped circuit model of the amphibian myelinated axon based on Frankenhaeuser-Huxley (FH) equations. The ultra-high frequency stimulation produces constant activation of both sodium and potassium channels at the axonal node under the block electrode causing the axonal conduction block. This blocking mechanism is different from the mechanism when the stimulation frequency is between 4 kHz and 10 kHz, where only the potassium channel is constantly activated. The minimal stimulation intensity required to induce a conduction block increases as the stimulation frequency increases. The results from this simulation study are useful to guide future animal experiments to reveal the different mechanisms underlying nerve conduction block induced by high-frequency biphasic electrical current.     

Influence of frequency and temperature on the mechanisms of nerve conduction block induced by high-frequency biphasic electrical current

The influences of stimulation frequency and temperature on mechanisms of nerve conduction block induced by high-frequency biphasic electrical current were investigated using a lumped circuit model of the myelinated axon based on Schwarz and Eikhof (SE) equations. The simulation analysis showed that a temperature-frequency relationship was determined by the axonal membrane dynamics (i.e. how fast the ion channels can open or close.). At a certain temperature, the axonal conduction block always occurred when the period of biphasic stimulation was smaller than the action potential duration (APD). When the temperature decreased from 37 to 15 degrees C, the membrane dynamics slowed down resulting in an APD increase from 0.4 to 2.4 ms accompanied by a decrease in the minimal blocking frequency from 4 to 0.5 kHz. The simulation results also indicated that as the stimulation frequency increased the mechanism of conduction block changed from a cathodal/anodal block to a block dependent upon continuous activation of potassium channels. Understanding the interaction between the minimal blocking frequency and temperature could promote a better understanding of the mechanisms of high frequency induced axonal conduction block and the clinical application of this method for blocking nerve conduction.     

Blockade of reflex venous capacitance responses in liver and spleen by hexamethonium, atropine, and surgical section.

Since hexamethonium and surgical section have been used to prevent reflex splanchnic capacitance responses, we examined the effectiveness of these procedures in blocking responses to direct stimulation of preganglionic fibres in the splanchnic nerves. Liver blood volume was measured by plethysmography and splenic blood volume by weighing in cats anesthetized by pentobarbital. The cats were adrenalectomized to prevent adrenal catecholamine secretion in response to splanchnic nerve stimulation. Hexamethonium (10 and 20 mg/kg) alone or atropine (1 mg/kg) alone caused only a small variable block of the responses to preganglionic nerve stimulation. A combination of the two drugs essentially produced a complete block of the liver capacitance response, but a significant response still persisted in the spleen. Surgical section of the postganglionic nerve bundles around the hepatic and splenic arteries completely abolished the responses to preganglionic stimulation. It is concluded that a relatively complete block of reflex splanchnic capacitance responses requires either a combination of hexamethonium and atropine or surgical section of the postganglionic nerves.     

Simulation of high-frequency sinusoidal electrical block of mammalian myelinated axons

High frequency alternating current (HFAC) sinusoidal waveforms can block conduction in mammalian peripheral nerves. A mammalian axon model was used to simulate the response of nerves to HFAC conduction block. Sinusoidal waveforms from 1 to 40 kHz were delivered to eight simulated axon diameters ranging from 7.3 to 16 μm. Conduction block was obtained between 3 to 40 kHz. The minimum peak to peak current at which block was obtained, defined as the block threshold, increased with increasing frequency. Block threshold varied inversely with axon diameter. Upon initiation, the HFAC waveform produced one or more action potentials. These simulation results closely parallel previous experimental results of high frequency motor block of the rat sciatic and cat pudendal nerve. During HFAC block, the axons showed a dynamic steady state depolarization of multiple nodes, strongly suggesting a depolarization mechanism for HFAC conduction block. Action Editor: Karen Sigvardt     

High-Frequency Stimulation of Excitable Cells and Networks

High-frequency (HF) stimulation has been shown to block conduction in excitable cells including neurons and cardiac myocytes. However, the precise mechanisms underlying conduction block are unclear. Using a multi-scale method, the influence of HF stimulation is investigated in the simplified FitzhHugh-Nagumo and biophysically-detailed Hodgkin-Huxley models. In both models, HF stimulation alters the amplitude and frequency of repetitive firing in response to a constant applied current and increases the threshold to evoke a single action potential in response to a brief applied current pulse. Further, the excitable cells cannot evoke a single action potential or fire repetitively above critical values for the HF stimulation amplitude. Analytical expressions for the critical values and thresholds are determined in the FitzHugh-Nagumo model. In the Hodgkin-Huxley model, it is shown that HF stimulation alters the dynamics of ionic current gating, shifting the steady-state activation, inactivation, and time constant curves, suggesting several possible mechanisms for conduction block. Finally, we demonstrate that HF stimulation of a network of neurons reduces the electrical activity firing rate, increases network synchronization, and for a sufficiently large HF stimulation, leads to complete electrical quiescence. In this study, we demonstrate a novel approach to investigate HF stimulation in biophysically-detailed ionic models of excitable cells, demonstrate possible mechanisms for HF stimulation conduction block in neurons, and provide insight into the influence of HF stimulation on neural networks.     

The actions of phenol and pentachlorophenol (PCP) on axonal conduction, ganglionic synaptic transmission, and the effect of pH changes

1. A comparison of phenol, pentachlorophenol (PCP) and procaine effects on axonal conduction were studied in vitro in the sciatic nerves of toad. PCP and procaine were respectively 6.3 and 3.15 times more potent than phenol in blocking axonal conduction. 2. Effects of PCP on synaptic transmission were studied in vitro in the eighth sympathetic ganglion of toad. 3. Axonal conduction block and synaptic transmission block by phenol was reversible, but not that by PCP. 4. When the PCP ionization was increased, a lesser per cent reached the site of action, reducing its capacity to block the axonal conduction and ganglionic transmission. 5. PCP plus, 3,4-Diaminopyridine (3,4-DAP) decreased synaptic transmission block from post-ganglionic compound action potential (CAP) responses to supramaximal preganglionic stimulation.     

Response of single alpha motoneurons to high-frequency pulse trains. Firing behavior and conduction block phenomenon

Studies were conducted on 25 cats to document the discharge rates of alpha motoneurons during stimulation of the sciatic nerve at frequencies from 100 to 10,000 pulses per second (pps). In addition, the feasibility of using high-frequency pulse trains to block the conduction of action potentials was investigated. Two cuff electrodes were placed around the proximal portion of the left sciatic nerve, and recordings of antidromic potentials were taken from single fibers of the L7 ventral root. When stimulating through the more proximal electrode, discharge rates were generally equal to or were subharmonics of the stimulation rate up to 1,000 pps. Firing often decreased in rate during 3-min runs. At 2,000-10,000 pps, fibers responded briefly at rates of several hundred per second but stopped firing within seconds after stimulus initiation. After cessation of response to the high-frequency pulse train, action potentials generated at 50 pps at the more distal electrode did not propagate to the recording electrodes. The 'electrical block' so induced was maintained for up to 20 min, and recovery following termination of the pulse train was complete within 1 s.     

Phosphoinositide metabolism in rat superior cervical ganglion, vagus and phrenic nerve: effects of electrical stimulation and various blocking agents

Abstract— Paired vagus nerves, phrenic nerves or superior cervical ganglia from rats were incubated at 37 C for various times in a simple salt solution containing glucose and ³²P_i. One of the pair was usually stimulated electrically for 30 or 60 min. Stimulation of vagus nerve for 30 min increased phosphate incorporation into all the phospholipids studied but the increase was significant only in the case of triphos-phoinositide and diphosphoinositide. This increase was not accompanied by increased labelling of the nucleotide labile phosphate pool. Tetrodotoxin at concentrations sufficient to block transmission had no effect upon phospholipid labelling in vagus or phrenic nerve. Ouabain at blocking concentration did not affect polyphosphoinositide metabolism in vagus nerve but increased [³²P]labelling of the other phospholipids. Hemicholinium-3 increased the labelling of all three phosphoinositides in the sympathetic ganglia but the increase in phosphatidylinositol labelling due to electrical stimulation was not seen in the presence of this inhibitor.