几种杀虫剂对棉铃虫头部酯酶的联合抑制作用

测定了几种药剂及其组合对棉铃虫Helicoverpa armigera头部酯酶活性的独立与联合抑制作用。结果显示：久效磷、敌百虫、呋喃丹对酯酶活性抑制中浓度分别为:2.4443×10^-6、3.4562×10^-7、2.6302×10^-5mol/L。药代动力学分析结果显示:久效磷与呋喃丹对酯酶抑制方式为竞争性抑制,敌百虫为非竞争性抑制。久效磷+敌百虫与敌百虫+呋喃丹两种药剂组合处理后,对酯酶抑制均增强,抑制中浓度分别为:1.0846×10^-6、5.1786×10^-6mol/L,对酯酶的抑制作用属非竞争性抑制作用。而久效磷+呋喃丹组合对酯酶抑制活性相加,为竞争性抑制作用。结果说明杀虫剂与酯酶的药代动力学互作对混剂的酯酶的抑制作用方式和活性具有重要影响。     

九种常用杀虫剂对二化螟线粒体ATPase活力的抑制作用

研究了二化螟Chilo suppressalis线粒体Na⁺-K⁺-ATPase和Ca^2＋-Mg^2＋-ATPase的生物化学性质以及9种常用杀虫剂对这两种酶活性的影响。结果表明, 二化螟线粒体Na⁺-K⁺-ATPase和Ca^2＋-Mg^2＋-ATPase的最适反应条件为pH值7.4,温度37℃。 Na⁺-K⁺-ATPase的米氏常数（Km）为0.42 mmol/L,最大反应速度（Vmax）为302.47 nmol/(min·mg) 。Ca^2＋-Mg^2＋-ATPase的Km为0.40 mmol/L,Vmax为128.04 nmol/(min·mg)。药剂浓度为1×10^-4 mol/L时,5种菊酯类杀虫剂对离体ATPase活性抑制的顺序为：溴氰菊酯>联苯菊酯>百树菊酯>三氟氯氰菊酯和氟硅菊酯;对二化螟Na⁺-K⁺-ATPase的抑制率分别为40.12％、39.69％、27.27％、19.49％和18.71％;对Ca^2＋-Mg^2＋-ATPase的抑制率分别为29.27％、23.78％、19.88％、11.64%和14.34％。硫丹对二化螟Na⁺-K⁺-ATPase和Ca^2＋-Mg^2＋-ATPase的抑制率均为17.46％。甲胺磷和呋喃丹对Ca^2＋-Mg^2＋-ATPase的抑制率分别为27.16％和17.42％,对Na⁺-K⁺-ATPase则几乎没有抑制作用。实验结果还表明, 在1.6×10^-7～1×10^-4 mol/L的浓度范围内,上述9种杀虫剂对二化螟ATPase活性的抑制率存在明显的剂量-效应关系。     

溴氰菊酯对不同品系家蝇脑突触体膜蛋白磷酸化及ATP酶活性的影响

以敏感品系家蝇和溴氰菊酯抗性品系家蝇(Musca domestica L.)为材料,研究和比较了神经毒剂溴氰菊酯对其脑突触体蛋白磷酸化作用的影响。结果表明,浓度为10^-5 mol/L溴氰菊酯抑制了敏感品系家蝇脑突触体蛋白磷酸化作用,而对抗性品系家蝇脑突触体蛋白磷酸化作用无明显影响。若反应体系中加入2.5×10^-6 mol/L的cAMP显著激活了敏感品系家蝇脑突触体蛋白磷酸化水平,但是当0.6 mmol/Lca²⁺或0.6 mmol/L Ca²⁺加10^-5 mol/L钙调蛋白时明显增强了抗性品系家蝇脑突触体蛋白磷酸化水平,甚至超过了其对敏感品系的作用水平。此外,还发现不同浓度的溴氰菊酯可抑制突触膜上的Na/K-ATP酶和Ca-ATP酶活力,浓度越高抑制作用也越大,并且敏感品系家蝇对溴氰菊酯的敏感度要高于抗性品系。     

CdSe量子点荧光猝灭法测定尿嘧啶

以CdSe量子点为荧光探针,基于荧光猝灭法对碱基尿嘧啶进行了定量检测,考察了缓冲液体系、反应时间、量子点浓度等多种因素的影响. 实验结果表明,在pH 7.4的0.2 mol/L Na₂HPO₄-NaH₂PO₄缓冲液中,反应时间为60 min,尿嘧啶浓度为10^-6～10^-4mol/L范围时,其线性回归方程为F₀/F =0.992+3.35×10⁴Q (mol/L),检测限为3.23×10^-6 mol/L(即0.36μg/ml). 该方法检测范围宽,灵敏度高,为尿嘧啶的测定提供了新的方法.     

神经递质3H-去甲肾上腺素释放与家蝇对拟除虫菊酯抗性的关系

在用K⁺去极化条件下,研究了溴氰菊酯和氯菊酯分别对敏感、抗溴氰菊酯和抗氯菊酯家蝇Musca domestica 品系脑突触体释放神经递质去甲肾上腺素的影响。结果表明：在用K⁺去极化后,神经递质去甲肾上腺素的释放在抗溴氰菊酯和抗氯菊酯家蝇品系中比敏感品系分别下降47.0%和51.0%;当用10^-5 mol/L溴氰菊酯预处理家蝇脑突触体,用K+去极化后对敏感、抗溴氰菊酯和抗氯菊酯家蝇品系释放去甲肾上腺素的加强作用分别提高80.3%、26.5%和70.5%;用10^-5 mol/L氯菊酯预处理3个家蝇品系的突触体对去甲肾上腺素释放均无加强作用。由此表明,家蝇对溴氰菊酯的抗性是与Na+通道的亲和性降低有关,而氯菊酯的抗性与Na+通道的亲和性关系不大。     

光学活性拟除虫菊酯对棉铃虫神经细胞钠通道电流的影响

用全细胞膜片钳技术对比分析了alpha体氯氰菊酯与theta体氯氰菊酯对棉铃虫Helicoverpa armigera幼虫离体培养中枢神经细胞Na⁺通道门控过程的影响。结果表明,alpha体氯氰菊酯作用后,神经细胞Na⁺通道电流（I_Na）先增大,同时通道的激活电压向负电位方向移动约10 mV,提示alpha体氯氰菊酯使通道激活电位降低,通道更容易被激活。药剂作用约10 min后,I_Na又迅速降低,表明alpha体氯氰菊酯对开放状态的Na⁺通道有抑制作用。另外,alpha体氯氰菊酯使I_Na到达峰值的时间缩短,但对失活时间无明显影响。Theta体氯氰菊酯也使I_Na激活电位左移,幅值降低,但降低速率较慢。总的结果表明alpha体氯氰菊酯与theta体氯氰菊酯对棉铃虫中枢神经细胞处于关闭和开放状态的钠通道均有作用,且alpha体氯氰菊酯对钠通道电流的抑制作用强于theta体氯氰菊酯。     

黑翅土白蚁乙酰胆碱酯酶最佳反应体系的建立及药剂敏感度比较

用正交试验方法研究了酶浓度、底物浓度、反应体系pH值、反应温度、反应时间5个因素对黑翅土白蚁Odontotermes formosanus (Shiraki)乙酰胆碱酯酶(AChE)活性测定的影响。通过对正交试验结果进行极差和方差分析,明确了测定黑翅土白蚁AChE活性的最适反应条件是酶浓度为12.5 g/L,底物浓度为8 mmol/L,pH值8.0,反应温度40℃,反应时间5 min。此外,研究了6种药剂对黑翅土白蚁体内AChE活性的影响。结果表明：灭多威、辛硫磷、三唑磷、丙溴磷、马拉硫磷和氧化乐果6种药剂对黑翅土白蚁AChE抑制中浓度(IC₅₀)分别为3.52×10^-4,1.86×10^-3,5.13×10^-3,9.55×10^-4,8.81×10^-3,和1.39×10^-2 mol/L。在3.3×10^-7～5×10^-3 mol/L的浓度范围内,上述6种药剂对黑翅土白蚁体内AChE活性的抑制作用都具有明显的剂量效应关系。     

9种Na+通道mRNA在5个不同发育阶段大鼠16种组织中表达及变化趋势

电压-门控Na⁺通道由1个可单独发挥作用的α亚单位和2～4个起辅助作用的β亚单位构成,在可兴奋细胞动作电位的产生及传导等过程中起重要作用.采用RT-PCR法对5个不同发育阶段(P1、P9、P40、P80、P120)Wistar大鼠16种不同组织的9种Na⁺通道α亚单位及1种β亚单位的mRNA进行检测发现：同种类型Na⁺通道mRNA在大鼠不同组织中的表达不同,不同类型Na⁺通道mRNA在大鼠同一组织中的表达不同.其中,神经系统和心肌组织中Na⁺通道mRNA的表达最高,随着日龄的增加,Na⁺通道mRNA在不同组织中表达的变化趋势不同.Na⁺通道在全身组织中的广泛分布及随发育周期的不同变化趋势,为离子通道病的研究及治疗提供了理论基础.     

溴氰菊酯对神经细胞钙通道和 钙库的激活作用

应用膜片钳全细胞记录方式和显微荧光测钙技术,以MN9D神经细胞为材料研究了溴氰菊酯的作用机理。低浓度(10^-9 mol/L～10^-7 mol/L)溴氰菊酯就能使神经细胞Ca²⁺电流显著增加。10^-9 mol/L,1 min时电流增加平均值为20.64%,5 min时为15.48%,表明溴氰菊酯能激活高电位激活钙通道(L型和N型),促使Ca²⁺内流,显微荧光测定细胞内自由钙离子浓度（［Ca²⁺］_I）发现,在含Ca²⁺和无Ca²⁺的胞外液中,溴氰菊酯均能使胞内自由钙离子数量增加,表明它能刺激胞内钙库释放Ca²⁺。［Ca²⁺］_I升高对细胞功能影响很大。     

一种菊酯类复合剂对黑胸散白蚁体内CarEs和Ca-ATPase活性的影响

以黑胸散白蚁Reticulitermes chinensis Snyder为试验材料,研究了一种白蚁防治复合剂中的主要成分对白蚁体内羧酸酯酶（CarEs）和钙 腺苷三磷酸酶（Ca-ATPase）的影响。结果表明：氯菊酯在终浓度为1.66×10^-4 mol·L^-1以下时,对羧酸酯酶无明显抑制作用;八氯二丙醚和壬基酚聚氧乙烯醚在此浓度下都对羧酸酯酶表现出明显抑制作用,其IC₅₀分别为7.1148×10^-5 mol·L^-1和7.3373×10^-4 mol·L^-1;氯菊酯对Ca-ATPase表现出较强抑制作用,IC₅₀为5.11×10^-7 mol·L^-1。认为Ca-ATPase是黑胸散白蚁体内拟除虫菊酯类杀虫剂作用的主要靶标之一。     

Pyrethroid insecticides: Actions of deltamethrin and related compounds on insect axonal sodium channels

The actions of deltamethrin and eight other pyrethroids were tested on isolated giant axons of the cockroach Periplaneta americana, using microelectrode and oil-gap, single-fibre electrophysiological recording techniques. Deltamethrin at micromolar concentrations induced a slow progressive depolarization of the axon membrane accompanied by a gradual reduction in action potential amplitude. The deltamethrin-induced depolarization was enhanced by an increase in stimulation frequency and was reduced in the presence of the sodium channel blocking agent saxitoxin (1 × 10^?7 M).Other synthetic pyrethroids (biopermethrin and its 1S enantiomer, biotetramethrin, s-bioallethrin, bioresmethrin and its 1S enantiomer, cismethrin and kadethrin) were also studied. In contrast to the findings with deltamethrin all other compounds, apart from the 1S isomers which were inactive, induced prolonged negative (depolarizing) after-potentials. Deltamethrin appears to affect a small fraction of sodium channels which are held in a modified open-state, whereas the pyrethroids which generate large negative after-potentials appear to induce a brief alteration of the open-state sodium channels with a larger number of channels affected. Differences between the actions of pyrethroids on insect axonal sodium channels and whole insects are discussed.     

Current-dependent block of nerve membrane sodium channels by paragracine.

Paragracine, isolated from the coelenterate species Parazoanthus gracilis, selectively blocks sodium channels of squid axon membranes in a frequency-dependent manner. The blocking action depends on the direction and magnitude of the sodium current rather than on the absolute value of the membrane potential. Paragracine blocks the channels only from the axoplasmic side and does so only when the current is in the outward direction. This block may be reversed by generating inward sodium currents. In axons in which sodium inactivation has been removed by pronase, the frequency-dependent block persists, and a slow time-dependent block is observed. A slow interaction with its binding site in the channel may account for the frequency-dependent block.     

Interaction of deoxycholate with the sodium channel of squid axon membranes

Deoxycholate can react with sodium channels with a high potency. The apparent dissociation constant for the saturable binding reaction is 2 microM at 8 degrees C, and the heat of reaction is approximately -7 kcal/mol. Four independent test with Na-free media, K-free media, tetrodotoxin, and pancuronium unequivocally indicate that it is the sodium channel that is affected by deoxycholate. Upon depolarization of the membrane, the drug modified channel exhibits a slowly activating and noninactivating sodium conductance. The kinetic pattern of the modified channel was studied by increasing deoxycholate concentration, lowering the temperature, chemical elimination of sodium inactivation, or conditioning depolarization. The slow activation of the modified channel can be represented by a single exponential function with the time constant of 1--5 ms. The modified channel is inactivated only partially with a time constant of 1 S. The reversal potential is unchanged by the drug. Observations in tail currents and the voltage dependence of activation suggest that the activation gate is actually unaffected. The apparently slow activation may reflect an interaction betweem deoxycholate and the sodium channel in resting state.     

A [Na+]o-independent, pHo-dependent mechanism for reduction of intracellular [Ca2+] after influx through Ca2+ channels in mouse pituitary cells

The effect of extracellular pH (pHo) on the duration of calcium-dependent chloride currents (ICl(Ca] was studied in voltage clamped AtT-20 pituitary cells. ICl(Ca) was activated by Ca2+ influx through plasma membrane Ca2+ channels, which were opened by step depolarization to voltages between -20 and +60 mV. Increasing pHo from 7.3 to 8.0 reversibly prolonged ICl(Ca) tail currents in perforated patch recordings from cells bathed in both Na(+)-containing and Na(+)-free solutions. This prolongation was prevented in standard whole cell recordings when the pipette solution contained 0.5 mM EGTA. The effects of raised pHo were not due to alteration of intracellular pH, since tail current prolongation still occurred when intracellular pH was buffered at 7.3 with 80 mM HEPES. The prolongation of ICl(Ca) at pHo 8 could not be accounted for by a direct action on Ca2+ channels, since tail currents were prolonged when pHo was changed rapidly during the tail current, after all Ca2+ channels were closed. The effects of increasing pHo on ICl(Ca) also could not be explained by a direct action on Cl- channels, since changing to pHo 8 did not prolong Cl- tail currents when intracellular Ca2+ concentration [( Ca2+]i) was fixed by EGTA in whole cell recordings. Raising pHo did, however, prolong depolarization-evoked [Ca2+]i transients, measured directly with the Ca2+ indicator dye, fura-2. Taken together, these data demonstrate the presence of a Na(+)-independent, pHo-sensitive mechanism for reduction of [Ca2+]i after influx through Ca2+ channels. This mechanism is associated with the plasma membrane, and is active on a time scale that is relevant to the duration of single action potentials in these cells. We suggest that this mechanism is the plasma membrane Ca2+ ATPase.     

A theory for the membrane potential of living cells

We give an explicit formula for the membrane potential of cells in terms of the intracellular and extracellular ionic concentrations, and derive equations for the ionic currents that flow through channels, exchangers and electrogenic pumps. We demonstrate that the work done by the pumps equals the change in potential energy of the cell, plus the energy lost in downhill ionic fluxes through the channels and exchangers. The theory is illustrated in a simple model of spontaneously active cells in the cardiac pacemaker. The model predicts the experimentally observed intracellular ionic concentration of potassium, calcium and sodium. Likewise, the shapes of the simulated action potential and five membrane currents are in good agreement with experiment. We do not see any drift in the values of the concentrations in a long time simulation, and we obtain the same asymptotic values when starting from the full equilibrium situation with equal intracellular and extracellular ionic concentrations. Received: 9 December 1998 / Revised version: 30 August 1999 / Accepted: 15 October 1999     

Saturation effects and rectifier properties of sodium channels in human skeletal muscle

Sodium outward currents were measured in human myoballs with the whole-cell recording method. The electro-chemical gradient of the sodium ions across the cell membrane was modified over a wide range by variations of the clamped membrane potential and of the internal and external soidum concentration. Up to 50 mV positive to the sodium equilibrium potential, E_Na, the current-voltage relation is linear. At a potential 80 mV positive to E_Na the sodium outward current has a maximum and decreases with a further increase in electrochemical gradient. Investigating the instantaneous current change in experiments in which the membrane potential was changed while the channels were already open we could exclude the possibility that the gates of activation or inactivation are responsible for this effect. Therefore we postulate that the sodium channel has a valve-like mechanism producing a negative slope conductance at highly positive membrane potentials, a current saturation with self-inhibition by the intracellular sodium concentration, and a blockade of the channel on reduction of the extracellular sodium concentration.This work was supported by the Deutsche Forschungsgemeinschaft (Ru 138/15-1, 15-2)     

Action of External Divalent Ion Reduction on Sodium Movement in the Squid Giant Axon

Voltage clamp measurements of the sodium potential have been made on the resting squid giant axon to study the effect of variations in external divalent ion concentration upon net sodium flux. From these measurements the intracellular sodium concentration and the net sodium inflow were calculated using the Nernst relation and constant activity coefficients. While an axon bathed in artificial sea water shows a slow increase in internal sodium concentration, the rate of sodium accumulation is increased about two times by reducing external calcium and magnesium concentrations to 0.1 times their normal values. The mean inward net sodium flux increases from a mean control value of 97 pmole/cm² sec. to 186 pmole/cm² sec. in low divalent solution. Associated with these effects of external divalent ion reduction are a marked decrease in action potential amplitude, little or no change in resting potential, and a shift along the voltage axis of the curve relating peak sodium conductance to membrane potential similar to that obtained by Frankenhaeuser and Hodgkin (1957). These results implicate divalent ions in long term (minutes to hours) sodium permeability.     

Kinetics of interaction of disopyramide with the cardiac sodium channel: Fast dissociation from open channels at normal rest potentials

Block of cardiac sodium channels is enhanced by repetitive depolarization. It is not clear whether the changes in drug binding result from a change in affinity that is dependent on voltage or on the actual state of the channel. This question was examined in rabbit ventricular myocytes by analyzing the kinetics of block of single sodium channel currents with normal gating kinetics or channels with inactivation and deactivation slowed by pyrethrin toxins. At −20 and −40 mV, disopyramide 100 μm blocked the unmodified channel. Mean open time decreased45 and34% at −20 and −40 mV during exposure to disopyramide. Exposure of cells to the pyrethrin toxins deltamethrin or fenvalrate caused at least a tenfold increase in mean open time, and prominent tail currents could be recorded at the normal resting potential. The association rate constant of disopyramide for the normal and modified channel at −20 mV was similar, ∼10×10⁶/m/sec. During exposure to disopyramide, changes in open and closed times and in open channel noise at −80 and −100 mV are consistent with fast block and unblocking events at these potentials. This contrasts with the slow unbinding of drug from resting channels at similar potentials. We conclude that the sodium channel state is a critical determinant of drug binding and unbinding kinetics.     

Effects of capsaicin on molluscan neurons: a voltage clamp study

The effects of capsaicin (CAP) on membrane ionic currents of identified and non-identified neurons were investigated by use of the single electrode clamp (SEC). CAP (300 microM, 22 degrees C, pH 7.4) caused a 25-50% reduction of the inward current and a 50-80% reduction of the outward current in normal or Na-free (Tris) solution. The Na current (INa) was moderately decreased (about 10%) in LPa2 neuron, but a 50% reduction of the peak Ca current (ICa) was observed. The action of CAP on ICa varied from cell to cell but an enhanced inactivation of the fast calcium current was found in all neurons studied. CAP (150 microM, 10 min) highly attenuated the long-lasting component of the inward current in LPa2 recorded in Na-free (TEA) Ba solutions. CAP attenuated the fast outward current (IA) and voltage-dependent outward current (IK) in 100 and 300 microM concentrations for the half blocking dose (ID50) in LPa2 neuron, respectively. CAP decreased the slow outward tail currents but hardly influenced the leakage current (IL). We suggest that the acute action of CAP coupled with a series of events in the neuronal membrane can modify the conductance via electrically excitable calcium, potassium and sodium channels differentially.     

丹参酮Ⅱ—A磺酸钠对分离的豚鼠心室肌单细胞慢反应...

The sodium channels of dissociated single ventricular cells of adult guinea pig heart were inactivated by partial depolarization in high K+ (25 mmol/L) Tyrode's solution and slow response action potential was elicited by intracellular stimulation. An obvious inhibition of the response was observed in the presence of 20 mumol/L sodium tanshinone II-A sulfonate (DS-201). In the concentration range from 1 mumol/L to 20 mumol/L, the inhibition effect of sodium tanshinone II-A sulfonate on the slow response action potentials enhanced by 0.28 mumol/L isoprenaline is concentration-dependent. Moreover, the inhibition effects of sodium tanshinone II-A sulfonate become stronger with the increase (in the range of 6.9 nmol/L to 0.55 mumol/L) of isoprenaline. The above-mentioned results suggest that sodium tanshinone II-A sulfonate may be a kind of effective calcium channel blocker. Under the effect of high concentration (50-100 mumol/L) of sodium tanshinone II-A sulfonate, the amplitude of fast response action potential of dissociated ventricular myocytes of adult guinea pig was decreased and the time to reach the peak was prolonged. All these results indicate that sodium channels were blocked to a certain extent by the high concentration of sodium tanshinone II-A sulfonate.