体外培养新生大鼠大脑皮层星形神经元钾通道的特性及膜外钾离子浓度对其影响

用膜片钳技术中的细胞贴附方式和内面向外方式,首次在新生大鼠大脑皮层星形神经元胞体膜上记录到一类电压依赖性钾通道。此通道可被２０ｍｍｏｌ／ＬＴＥＡ,５ｍｍｏｌ／ＬＢａ２＋,１４０ｍｍｏｌ／ＬＣｓ＋阻断,不受２０ｍｍｏｌ／Ｌ４—ＡＰ影响,其激活不依赖Ｃａ２＋。膜外钾离子浓度对通道的特性有显著的影响,逆转电位随［Ｋ＋］０的增大而增大,并表现出一定的饱和现象,两者的对数呈线性关系;同一驱动电位下,平均开放时间和开放概率随［Ｋ＋］０的增大而增大,平均关闭时间的变化则相反。     

川芎嗪对蟾蜍交感神经节细胞膜嘌呤受体介导反应的调制作用

采用细胞外微电极技术,记录离体灌流的蟾蜍椎旁交感神经节细胞膜电位,观察川芎嗪对嘌呤受体介导反应的调制作用。三磷酸腺苷（３００μｍｏｌ／Ｌ）可引起神经节细胞膜去极化（ｎ＝６２）、超极化反应（ｎ＝２７）以及去极化之后伴随超极化过程的双相反应（ｎ＝９）。Ｐ２受体拮抗剂台盼蓝（５００μｍｏｌ／Ｌ）可抑制三磷酸腺苷的去极化反应（ｎ＝８）;Ｐ１受体拮抗剂氨茶碱（２００μｍｏｌ／Ｌ）可抑制三磷酸腺苷的超极化反应（ｎ＝７）。滴加川芎嗪（１～５ｍｍｏｌ／Ｌ）,神经节细胞膜未出现明显的电位变化。外源性环－磷酸腺苷（２５０μｍｏｌ／Ｌ）可模拟三磷酸腺苷的超极化反应（ｎ＝９）。川芎嗪（３ｍｍｏｌ／Ｌ）可抑制三磷酸腺苷的去极化反应,使其幅值减少５３９±９５％（ｎ＝１４,Ｐ＜００１）,并能加强三磷酸腺苷所致超极化反应,使其幅值增大１０５４±２４５％（ｎ＝１２,Ｐ＜００１）。在同一标本上,川芎嗪使环一磷酸腺苷的超极化反应加强（ｎ＝４）。此外,川芎嗪可抑制三磷酸腺苷引起的双相反应中的去极相,而增大其后的超极相（ｎ＝３）。     

SNP抑制5-HT诱导的胞内游离钙浓度升高和内钙释放

用Ｆｕｒａ － ２／ＡＭ 荧光测量技术研究了５ － 羟色胺（５－ ＨＴ） 诱导的大鼠尾动脉平滑肌细胞胞内钙升高和一氧化氮（ＮＯ） 的抑制效应。实验表明, 胞外０ｍ ｍｏｌ／ Ｌ Ｃａ２ ＋ 时胞内静息［Ｃａ２ ＋ ］ ｉ 为２０ ．２±８ ．６ｎｍｏｌ／Ｌ（ｎ ＝ ８） 。１０μｍｏｌ／Ｌ ５－ ＨＴ 可诱导出胞内钙库释放引起的瞬态［Ｃａ２ ＋］ｉ 升高,其峰值达２４５ ．７ ±７１．６ｎｍｏｌ／ Ｌ（ｎ ＝ ６） 。１０ － ７ ｍｏｌ／Ｌ 硝普钠（ＳＮＰ） 可抑制５－ ＨＴ 诱导的［Ｃａ２ ＋］ｉ 升高,其峰值浓度降为７５．１±３５ ．９ｎｍｏｌ／Ｌ（ｎ ＝ ５） 。当细胞浴液含２．５ｍ ｍｏｌ／Ｌ Ｃａ２ ＋ 时,静息［Ｃａ２ ＋］ｉ为１１２ ．８ ±１０ ．３ｎｍｏｌ／ Ｌ（ｎ ＝ ５） , 这时１０μｍｏｌ／ Ｌ ５ － ＨＴ 可诱导［Ｃａ２ ＋ ］ ｉ 的峰值为２５２ ．３ ±８０ ．６ｎｍｏｌ／Ｌ（ｎ ＝ ４） ,以及其后平台浓度为１４３ ．０ ±３７ ．６ｎｍｏｌ／Ｌ（ｎ ＝ ４） ,略大于［Ｃａ２ ＋］ｉ 为１１２．８ ±１０ ．３ｎｍｏｌ／Ｌ 的静息浓度,为外钙内流引起。１０ － ７ ｍｏｌ／Ｌ ＳＮＰ 也可抑制５－ ＨＴ 诱导［Ｃａ２ ＋ ］ｉ 平台相浓度。平台浓度由１４３ ±４７     

体外培养新生大鼠大脑皮层星形神经元钾通道的特性及膜外钾离子浓度对其影响

用膜片钳技术中的细胞贴附方式和内面向外方式,首次在新生大鼠大脑皮层星形神经元胞体膜上记录到一类电压依赖性钾通道。此通道可被２０ｍｍｏｌ／Ｌ ＴＥＡ,５ｍｍｏｌ／Ｌ Ｂａ＾２＋,１４０ｍｍｏｌ／Ｌ Ｃｓ＾＋阻断,不受２０ｍｍｏｌ／Ｌ４－ＡＰ影响,其激活不依赖Ｃａ＾２＋。膜外钾离子浓度对通道的特性有显著的影响,逆转电位随Ｋ＾＋的增大而增大,并表现出一定的饱和现象,两者的对数呈线性关系;同一驱动电位下,     

褪黑素对大鼠海马神经元谷氨酸所致毒性的拮抗作用

在大鼠海马脑片上电刺激Ｓｃｈａｆｆｅｒ 侧支纤维, 胞外记录ＣＡ１ 区锥体细胞层诱发群体锋电位（ｐｏｐｕｌａｔｉｏｎ ｓｐｉｋｅ,ＰＳ） , 观察灌流谷氨酸（Ｇｌｕ） 和褪黑素（ＭＥＬ） 对ＰＳ的影响。结果显示：５－０ ｍｍｏｌ／Ｌ浓度的Ｇｌｕ 可使ＰＳ值下降至对照值的４－１ ％ ; ＭＥＬ（０－４ 、０－５ 和０－６ μｍｏｌ／Ｌ） 与５－０ ｍｍｏｌ／ＬＧｌｕ 混合给药,ＰＳ值分别变化为对照值的１４－７ ％ 、１０５－２％ 、２４－３ ％ ; ＭＥＬ（０－５ μｍｏｌ／Ｌ） 、Ｇｌｕ （５－０ ｍｍｏｌ／Ｌ） , 与赛庚啶（ＣＤＰ,０－５ μｍｏｌ／Ｌ） 混合给药,ＰＳ值下降至０ 。上述结果提示,５－０ ｍｍｏｌ／Ｌ浓度的Ｇｌｕ 有神经毒性作用, 但可为ＭＥＬ拮抗, 这可能由５ＨＴ受体所介导。     

褐黑素对大鼠海马神经元谷氨酸所致毒性的拮抗作用

在大鼠海马脑片上电刺激Ｓｃｈａｆｆｅｒ侧支纤维,胞外记录ＣＡ１区锥体细胞层诱发群体锋电位,观察灌流谷氨酸和褪黑素对ＰＳ的影响。结果显示：５．０ｍｍｏｌ／Ｌ浓度的Ｇｌｕ可使ＰＳ值下降至对照值的４．１％;ＭＥ（０．４、０．５和０．６μｍｏｌ／Ｌ）一５．０ｍｍｏｌ／Ｌ浓度的Ｇｌｕ可使ＰＳ值下降至对照值的１４．７％、１０５．２％、２４．３％;ＭＥＬ、Ｇｌｕ,与赛庚啶混合给药,ＰＳ值下降至０。上述结果提示。     

CCC浸种对小麦生长性状的影响

ＣＣＣ浸种的效应与其浓度密切相关。１０％的浓度明显降低出苗率;浓度低于５％对出苗率无影响。在０．１％－１０％之间,随浓度增高,茎叶干重降低,而根系干重增加。增加根系总长度的效果以０．１％－３％的浓度最好。浓度在５％范围内,叶绿素含量随浸种浓度的的升高而增加。浓度高于１％时叶面积减小。全面权衡,旱地小麦ＣＣＣ浸种最适宜的浓度为１％。     

培养的海马神经元致痫后谷氨酸的合成和释放的变化

通过谷氨酸（Ｇｌｕｔａｍａｔｅ,Ｇｌｕ）免疫细胞化学染色法观察到马桑内酯（ＣｏｒｉａｒｉａＬａｃｔｏｎｅ,ＣＬ）（２．５×１０－５ｍｏｌ／Ｌ）作用于体外培养的海马神经元６ｈ呈色增强,此后呈色反应明显减弱,阳性细胞数减少,胞体变小,突起短而稀少。ＭＫ－８０１（４×１０－５ｍｏｌ／Ｌ）可降低ＣＬ引起的海马神经元Ｇｌｕ免疫反应性。高效液相色谱法（ＨＰＬＣ）测定ＣＬ作用于培养的海马神经元２４ｈ后培养基中Ｇｌｕ和天门冬氨酸（Ａｓｐ）含量增加（Ｐ＜０．００１）,ＭＫ－８０１并不能阻断此种效应。结果提示ＣＬ致痫后,早期神经元内Ｇｌｕ合成增加,后期向胞外释放。     

钙离子和蛋白激酶C对大鼠缺血海马脑片谷氨酸堆积的影响

采用大鼠海马脑片体外缺血模型观察钙离子和蛋白激酶Ｃ（ＰＫＣ）对神经元胞外谷氨酸（ＧＬＵ）堆积的影响,结果显示：海马脑片在体外“缺血”１０ｍｉｎ,ＧＬＵ在胞外的浓度增加４倍（从３２±４升高到１１３±１０ｐｍｏｌ／（ｍｉｎ．ｍｇＰｒ）．ｎ＝６）．Ｎ型钙通道拮抗剂蝙蝠葛苏林碱（ＤＳＬ）或无钙培养液均能有效抑制这种浓度的升高（Ｐ＜０．０１）．提示缺血１０ｍｉｎ引发的ＧＬＵ浓度升高是受Ｃａ２＋内流调控的．当脑片在缺血状况下孵育３０ｍｉｎ,ＤＳＬ只部分抑制这种ＧＬＵ堆积,而无钙培养液则无影响,但这额外的ＧＬＵ堆积可被ＰＫＣ抑制剂Ｈ－７完全阻断,而被ＰＫＣ激动剂ＰＤＢ所加强;且不受钙调蛋白抑制剂Ｃａｌｍｄａｚｏｌｉｕｍ和８－溴－ｃＡＭＰ影响．提示缺血３０ｍｉｎ,胞外ＧＬＵ的堆积受钙内流和ＰＫＣ双重调控。     

荧光指示剂法测定植物细胞胞质游离Ca^2＋浓度

利用钙离子荧光指示剂Ｉｎｄｏ－１ ＡＭ 建立了测定植物细胞胞质游离Ｃａ２＋ 浓度的技术。应用此技术测出,ＢＭＳ（ｂｌａｃｋ Ｍｅｘｉｃｏ ｓｗ ｅａｔ）玉米悬浮细胞原生质体静息水平下的胞质游离Ｃａ２＋ 浓度是１２７±５６ ｎｍ ｏｌ·Ｌ－ １;Ｃａ２＋ 螯合剂ＥＧＴＡ 可使胞质游离Ｃａ２＋ 浓度由７８ ｎｍ ｏｌ·Ｌ－ １降至１２．５ ｎｍ ｏｌ·Ｌ－ １,而Ｃａ２＋ 载体Ａ２３１８７ 则可使胞质游离Ｃａ２＋ 浓度升至接近介质Ｃａ２＋ 水平。同时,证明ＡＢＡ 处理可使ＢＭＳ玉米悬浮细胞原生质体Ｃａ２＋ 浓度在１—１．５ 分钟内迅速升高,由７５ ｎｍ ｏｌ·Ｌ－ １升至７９０ ｎｍ ｏｌ·Ｌ－ １     

Electrophysiology of phagocytic membranes: III. Evidence for a calcium-dependent potassium permeability change during slow hyperpolarizations of activated macrophages

The roles of potassium and calcium in the slow hyperpolarizations of membranes of activated macrophages are investigated using standard intracellular electrical recording techniques.The amplitude of spontaneous slow hyperpolarizations decreases as a logarithmic function of the external potassium concentration in the culture medium. Similar dependence on the potassium gradient is observed when different levels of membrane potentials are imposed by constant current injection. The reversal potential for electrically evoked slow hyperpolarizations is ?90 mV. A 10-fold increase in external potassium concentration causes a 60 mV shift of the reversal potential towards zero.Divalent cation ionophores (A23187 and X537A) can induce slow hyperpolarization responses in quiescent cells or permanent hyperpolarization in spontaneously active cells. The amplitude of the ionophore-induced hyperpolarizations is reduced by an increase in external potassium concentration in a manner consistent with data on slow hyperpolarization responses in the absence of ionophore.The calcium antagonist, verapamil, depresses the slow hyperpolarization responses at the concentration of 10^?5 M.It is suggested that the development of the hyperpolarizing response is due to a calcium-dependent potassium channel. The data support the assumption that spontaneous and artificially elicited slow hyperpolarization responses share a common calcium-dependent mechanism.     

Electrophysiology of phagocytic membranes. III. Evidence for a calcium-dependent potassium permeability change during slow hyperpolarizations of activated macrophages

The roles of potassium and calcium in the slow hyperpolarizations of membranes of activated macrophages are investigated using standard intracellular electrical recording techniques. The amplitude of spontaneous slow hyperpolarizations decreases as a logarithmic function of the external potassium concentration in the culture medium. Similar dependence on the potassium gradient is observed when different levels of membrane potentials are imposed by constant current injection. The reversal potential for electrically evoked slow hyperpolarizations is -90 mV. A 10-fold increase in external potassium concentration causes a 60 mV shift of the reversal potential towards zero. Divalent cation ionophores (A23187 and X537A) can induce slow hyperpolarization responses in quiescent cells or permanent hyperpolarization in spontaneously active cells. The amplitude of the ionophore-induced hyperpolarizations is reduced by an increase in external potassium concentration in a manner consistent with data on slow hyperpolarization responses in the absence of ionophore. The calcium antagonist, verapamil, depresses the slow hyperpolarization responses at the concentration of 10(-5) M. It is suggested that the development of the hyperpolarizing response is due to a calcium-dependent potassium channel. The data support the assumption that spontaneous and artificially elicited slow hyperpolarization responses share a common calcium-dependent mechanism.     

Increased chloride conductance as the proximate cause of hydrogen ion concentration effects in Aplysia neurons

A fall in extracellular pH increased membrane conductance of the giant cell in the abdominal ganglion of Aplysia californica. Chloride conductance was trebled whereas potassium conductance was increased by 50%. Half the giant cells were hyperpolarized (2–8 mv) and half were depolarized (3–10 mv) by lowering the pH. The hyperpolarizing response always became a depolarizing response in half-chloride solutions. When internal chloride was increased electrophoretically, the hyperpolarization was either decreased or changed to depolarization. The depolarizing response was reduced or became a hyperpolarizing response after soaking the cell in 10.0 mM chloride, artificial seawater solution for 1 hr. Depolarization was unaffected when either external sodium, calcium, or magnesium was omitted. A glass micropipette having an organic liquid chloride ion exchanger in its tip was used to measure intracellular chloride activity in 14 giant cells; 7 had values of 27.7 ± 1.8 mM (SEM) and 7 others 40.7 ± 1.5 mM. Three of the first group were hyperpolarized when pH was lowered and three of the second group were depolarized. In all six cells, these changes of membrane potential were in the direction of the chloride equilibrium potential. Intracellular potassium activity was measured by means of a potassium ion exchanger microelectrode.     

An odorant-suppressed Cl– conductance in lobster olfactory receptor cells

Odorants evoke an outward current in cultured lobster olfactory receptor neurons voltage clamped at -60 mV. The reversal potential of the outward current is independent of the reversal potential of potassium, but shifts with imposed changes in the reversal potential of chloride. The slope of the current-voltage relationship is negative, suggesting that the current is mediated by the odorant suppressing a steady-state conductance. Anthracene-9-carboxylic acid, a specific chloride channel blocker, reversibly inhibits the steady-state conductance. Local application of odorants to the outer dendrites evokes a hyperpolarizing receptor potential in lobster olfactory receptor neurons current-clamped at -70 mV in situ. Consistent with the current characterized in the cultured cells, hyperpolarizing receptor potentials in some cells are voltage sensitive, blocked by anthracene-9-carboxylic acid and associated with a decrease in membrane conductance. These results support the hypothesis that odorants suppress a steady-state chloride conductance in lobster olfactory receptor neurons. Evidence that the chloride conductance can coexist with a 4-aminopyridine-blockable potassium conductance reported earlier in these cells suggests that two distinct mechanisms can mediate odorant-evoked inhibition in lobster olfactory receptor neurons.     

Effects of arginine-vasopressin and its derivatives on Helix pomatia cerebral neurons

Response to application of and superfusion with solutions containing arginine-vasopressin and its derivatives (VPS), was investigated in identifiedHelix pomatia neurons. Different VPS exerted a similar effect on neurons in all cases. De- and hyperpolarizing as well as modulatory effects were shown. Depolarizing and hyperpolarizing response was accompanied by a rise and fall in steady-state conductance of the cell membrane. Reversal potential of response was determined as in the region of chloride reversal potential. Adding furosemide to the extracellular solution reversibly inhibited response to VPS. It was concluded from this that both de- and hyperpolarizing response took the form of an increase in the amplitude of trans-membrane ionic current induced by injecting cAMP into the neuron under the effects of superfusing the preparation with a VPS-containing VPS solution. Specific VPS receptors, probably associated with the cell cyclic nucleotide system, are thought to exist at the membrane of someHelix pomatia neurons.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 22, No. 3, pp. 368–373, May–June, 1990.     

Possible existence of transient TTX-sensitive chloride current in the membrane of isolated cardiomyocytes

Cardiomyocytes enzymatically isolated from rat and guinea pig ventricular tissue were investigated under conditions of intracellular perfusion and voltage clamp at 18-20 degrees C. Perfusion with 135 mmol/l Tris(HF), pH 7.2 was used to eliminate outward potassium currents. The dependence of inward current (elicited by depolarizing pulses from a holding potential level of--120 mV) on low external TTX concentrations (from 10(-13) to 10(-10) mol/l) was studied. Similar TTX concentrations increased the amplitude of the inward current and changed its kinetics in a large number of cells tested. The effect was fully reversible. The effect could be evaluated in a net form by digital subtraction of the current obtained after the application of a low external TTX concentration from the initial current in a TTX-free solution. The TTX concentration dependence of the difference current could be fitted by one-to-one binding curve with Kd = (1.0 +/= 0.4) x 10(-12) mol/l. TTX-induced current changes were absent in low sodium or chloride-free external solutions. The outward current (a block of which by TTX produced the inward current changes observed) showed a reversal potential consistent with the chloride nature of such a current. The existence of a transient TTX-sensitive Na-dependent potential gated chloride current in the membrane of isolated cardiomyocytes is postulated.     

Studies on the mechanisms underlying horizontal-bipolar interaction in the carp retina.

Responses of on-center bipolar cells and horizontal cells were recorded simultaneously in the carp retina, and the effect of polarization of horizontal cells on the bipolar cells was studied. Hyperpolarization by extrinsic current of horizontal cells elicited in the bipolar cells a hyperpolarizing response which, unlike the electrical coupling betweeen adjacent horizontal cells, was accompanied by a change in membrane conductance. The bipolar cell responses elicited by polarization of external horizontal cells showed a negative reversal potential, while those elicited by polarization of intermediate horizontal cells showed a positive reversal potential. It was suggested that the external horizontal cells modify the cone-bipolar transmission which involves the conductance change of subsynaptic potassium and/or chloride channels, while the intermediate horizontal cells modify the rod-bipolar transmission which involves the conductance change of sodium channels.     

Voltage-gated ion conductances corresponding to regenerative positive and negative spikes in the dinoflagellateNoctiluca miliaris

Depolarization-activated and hyperpolarization-activated ion conductances in the membrane of a marine dinoflagellateNoctiluca miliaris were examined under voltage-clamp conditions.Noctiluca exhibited a transient inward current in response to a step depolarization from a holding potential level of –80 mV to a potential level more positive than –50 mV. The I–V relationship for the current exhibited typical N-shaped characteristics similar to those of most excitable membranes. The current was inactivated by a membrane depolarization. The reversal potential of the current shifted in hyperpolarizing direction when the external Na⁺ concentration was lowered. The transient inward current is assumed to be responsible for the Na⁺-dependent positive spike in non-clamped specimens ofNoctiluca.Noctiluca exhibited a transient outward current in response to a step hyperpolarization from a holding potential level of –20 mV to a potential level more negative than –30 mV. The I–V relationship for the current was a typical N-shape as if it was turned 180° around its origin. The outward current showed a two-step exponential time-decay. The outward current was inactivated by a membrane hyperpolarization. The reversal potential shifted in the depolarizing direction when the external Cl^– concentration was lowered. The transient outward current is responsible for the Cl^–-dependent negative spike in non-clamped specimens ofNoctiluca.Abbreviations ASW artificial seawater - TRP tentacle regulating potentials - TTX tetrodotoxin     

An active electrical response in fibroblasts

L cells have a resting potential of about -16 mv (internal negative) at 37°C in Dulbecco''s modified Eagle''s medium containing 10% fetal calf serum and a potassium concentration of 5.4 mM. Membrane resistivity is about 20,000 Ωcm² when the surface filopodia described by others are taken into account. Mechanical and electrical stimuli can evoke an active response from mouse L cells, cells of the 3T3 line, and normal fibroblasts which we have termed hyperpolarizing activation or the H.A. response. This consists of a prolonged (3–5 sec) increase in the membrane permeability by a factor of 2–10 with a parallel increase in membrane potential to about -50 mv. The reversal potential for the H.A. response is -80 mv. The resting cells are depolarized to about -12 mv when the external medium contains 27 mM potassium, and the potential reached at the peak of the H.A. response is about -30 mv. The reversal potential for the H.A. response is about -40 mv in 27 mM external potassium. This effect of potassium ions on the reversal potential of the H.A. response leads us to conclude that the response represents an increase in membrane permeability, predominantly to potassium, by at least a factor of five. This increase must be greater than 20-fold if previous measurements of the ratio of potassium permeability to chloride permeability in L cells are valid for the preparation used in the present study.     

Influence of chloride, potassium, and tetraethylammonium on the early outward current of sheep cardiac Purkinje fibers

In voltage clamp studies of cardiac Purkinje fibers, a large early outward current is consistently observed during depolarizations to voltages more positive than -20 mV. After the outward peak of the current, the total membrane current declines slowly. Dudel et al. (1967. Pfluegers Arch. Eur. J. Physiol. 294:197--212) reduced the extracellular chloride concentration and found that the outward peak and the decline of the current were abolished. They concluded that the total membrane current at these voltages was largely determined by a time- and voltage-dependent change in the membrane chloride conductance. We reinvestigated the chloride sensitivity of this current, taking care to minimize possible sources of error. When the extracellular chloride concentration was reduced to 8.6% of control, the principal effect was a 20% decrease in the peak amplitude of the outward current. This implies that the membrane chloride conductance is not the major determinant of the total current at these voltages. The reversal potential of current tails obtained after a short conditioning depolarization was not changed by alterations in the extracellular chloride or potassium concentrations. We suspect that the tail currents contain both inward and outward components, and that the apparent reversal potential of the net tail current largely reflects the kinetics of the outward component, so that this experiment does not rule out potassium as a possible charge carrier. The possibility that potassium carries much of the early outward current was further investigated using tetraethylammonium, which blocks potassium currents in nerve and skeletal muscle. This drug substantially reduced the early outward current, which suggests that much of the early outward current is carried by potassium ions.