去甲肾上腺素引起蟾蜍背根神经节神经细胞膜电位变化的离子机制

本文应用细胞内记录方法,对去甲肾上腺素(NA)引起蟾蜍背根神经节(DRG)神经细胞膜电位去极化或超极化反应时的膜电导及翻转电位值进行了测量,并观察了钾和钙离子通道阻断剂灌流DRG对NA引起膜电位反应的影响。当NA引起去极化反应时,15个细胞的膜电导减小32.6％。少数细胞膜电导开始增加,继而减小(n=4)。NA超极化反应时膜电导增加13.2％(n=8)。NA去极化反应的翻转电位值为-88.5±0.9mV((?)±SE,n=4),NA超极化反应在膜电位处于-89至-92mV时消失。 钾通道阻断剂四乙铵可使NA去极化幅值增加73.7±11.9％((?)±SE,n=7),并使NA超极化幅值减小40.5％(n=4)。细胞内注入氯化铯使苯肾上腺素去极化幅值增加34.5％(n=4)。钙通道阻断剂氯化锰使NA去极化及超极化反应分别减小50.5±9.9％((?)±SE,n=10)和89.5±4.9％((?)±SE,n=7)。结果提示,NA引起DRG神经细胞膜电位的去极化或超极化反应,可能与膜的钾及钙通道活动的改变有关。     

去甲肾上腺素对蟾蜍背根神经节细胞α-肾上腺素能受体的作用

在蟾蜍离体灌流背根神经节(DRG)标本上,用微电极进行细胞内记录。在51个细胞中A型神经元为46个,C型5个。此两类细胞的静息膜电位为60.06±1.34mV(x±SE)。当灌流液中滴加10~(-4)-10~(-3)mol/L去甲肾上腺素(NA)引起如下的膜电位改变:(1)超极化:幅值8.38±1.12mV(x±SE)(20/48);(2)去极化:幅值9.39±1.24mV(x±SE)(23/48);(3)无反应(5/48)。上述膜电位改变既不能由灌流液中滴加异丙基肾上腺素所拟似,也不能为心得安所阻断,因而排除了β-肾上腺能受体介导的可能性。加苯肾上腺素及可乐宁于灌流液,分别产生膜的去极化和超极化,而应用哌唑唪及育亨宾灌流,则分别阻断NA引起的膜去极化和超极化。因此认为:NA引起的DRG神经元的去极化和超极化反应分别是由胞体膜上之α_1-及α_2-肾上腺素能受体所介导的。     

去甲肾上腺素、乙酰胆碱对绵羊心肌浦肯野纤维瞬时性内向离子流的影响

用电压箝制术观察了去甲肾上腺素、乙酰胆碱对绵羊浦肯野纤维由乙酰毒毛旋花子甙元诱发的瞬时性内向离子流(I_Ti)的效应。当乙酰毒毛旋花子甙元浓度为4.5×10~(-8)mol/L 时,诱发出的I_(T1)稳定并能维持约1.5h。去甲肾上腺素1.5×10~(-6)mol/L,可使I_(Ti)的峰值由11.4±2.5nA 增加到14.5±4.1nA(n=11,P相似文献   

乙酰胆碱不依赖NO的释放引起耳蜗螺旋动脉平滑肌细胞的超极化

目的：乙酰胆碱（ACh）不仅是神经递质,也是一种有效的血管舒张物质参与许多血管床的调节活动。本实验观察ACh引起耳蜗螺旋动脉平滑肌细胞超极化的离子机制以及NO在超极化反应中的可能作用。方法：在豚鼠离体耳蜗螺旋动脉标本上,运用细胞内微电极技术记录外源性的ACh引起的反应。结果：在保持灌流液中含有5mmol／L K^＋以及最小纵向张力的情况下,ACh（0．1—10μmol／L）引起低静息膜电位细胞明显的超极化反应,而引起高静息膜电位细胞明显的去极化反应。ACh引起的平滑肌细胞超极化反应是浓度依赖性的（ACh的浓度是1μmol／L和10／μmol／L时,分别引起超极化的幅度是22和30mV,n=7）。ACh引起的超极化反应能被阿托品（atropine,0．1～1μmol／L,n=6）或DAMP（50～100nmol／L,n=6,一种选择性的地受体的拮抗剂）所阻断,同时也可被BAPTA—AM（10μmol／L,n=7,一种可通过细胞膜的Ca^2＋螯合剂）或eharybdotoxin＋apamin（50-100nmol／L,n=4,两种Ca^2＋激活K^＋通道的阻断剂）所阻断,但是Nω-nitro-L-arginine methyl ester（L-NAME,300μmol／L,n=8,一种NO合成酶的完全抑制剂,n≥5）或glipizide（10μmol／L,ATP敏感性的K^＋通道阻断剂,n=4）或indomethacin（10μmol／L,环氧合酶的抑制剂,n=4）不能阻断ACh引起的超极化反应。结论：ACh通过激活内皮细胞的M3受体,开放钙依赖的钾通道．进而引起耳蜗螺旋动脉平滑肌细胞产生超极化反应,并且这一超极化反应与内皮细胞NO的产生和释放无关。     

ACh对大鼠皮层体感区神经元延迟整流钾电流的抑制作用

利用全细胞膜片钳技术研究乙酰胆碱(acetylcholine,ACh)对大鼠皮层体感区神经元延迟整流钾电流(IK)的调制作用。结果表明:(1)ACh(0．1、1、10、100 μmol/L)对大鼠皮层体感区神经元IK有抑制作用,并具有剂量依赖性关系(P<0．01)。 (2)ACh可使IK激活曲线的斜率变大,并使激活曲线向超极化方向移动。IK激活曲线的半数激活电压(V1/12)和斜率因子(k)分别由给药前的(-41．8±9．7)mV和(30．7±7．2)mV变为给药后的(-122．4±38．6)mV和(42．4±7．0)mV。(3)100 μmol/L的N受体拮抗剂筒箭毒碱(tubocurarine)可减弱ACh对IK的抑制作用,在指令电压+60 mV时tubocurarine+ACh组的IK幅度下降了(16．9± 13．8)％(n=8),与10 μmol/L ACh组引起的(36．5±7．8)％的IK下降幅度相比,有极显著差异(P<0．01)。10 μmol/L的M1受体拮抗剂哌仑西平(pirenzepin)拮抗ACh对IK的抑制作用不明显(n=7,P>0．05);而10 μmol/L的M3受体拮抗剂4-DAMP可部分拮抗ACh对IK的抑制作用,并且4-DAMP+ACh组使IK的电流值下降了(26．8±4．7)％(n=6),与ACh组引起的IK电流下降相比,有显著差异(P<0．05)。(4)蛋白激酶C(protein kinase C,PKC)阻断剂chelerythrine拮抗ACh对IK的抑制作用,PKC激动剂PDBu可增强ACh对IK的抑制作用(P<0．05)。综上所述,ACh对人鼠皮层体感区神经元IK的抑制作用主要是通过烟碱受体(nAChRs)和M3受体介导,并经过PKC信号途径。     

大鼠背根节神经元后超极化中Ca^2＋激活K^＋电流的蜂毒明肽敏感成分 …

为了明确大鼠背根节(DRG)神经元中存在慢的Ca2+激活K+电流成分,本实验在新鲜分散的DRG神经元胞体上,采用全细胞电压箝技术,给予DRG神经元一定强度的去极化刺激,记录刺激结束后30 ms时的尾电流幅度.结果发现:(1)随着去极化时间从1 ms延长至180 ms时,尾电流幅度由9.3±2.8 pA逐渐增大至64.1±3.4 pA(P＜0.001);(2)当去极化结束后的复极化电位降低时,尾电流幅度先逐渐下降到零,然后改变方向,逆转电位约为-63 mV;(3)细胞外施加500μmol/L Cd2+或细胞内液中施加11 mmol/L EGYA时尾电流明显减小甚至完全消失;(4)尾电流中慢成分的幅度在细胞外给与200 nmol/L蜂毒明肽后,减小了约26.32±3.9%(P＜0.01);(5)细胞外施加10 mmol/L TEA,可明显降低尾电流中的快成分.结果提示,在DRG神经元后超极化中存在Ca2+激活K+电流的蜂毒明肽敏感成分--ⅠAiHP.     

GABA_A和GABA_B受体介导的蟾蜍背根神经节神经元胞体膜反应

实验在蟾蜍离体背根神经节(DRG)标本进行细胞内记录。浴槽滴加10~(-4)-10~(-3)mol/LGABA引起膜电位改变如下:(1)去极化(79/100);(2)双相反应;先为去极化,继后为超极化(10/100);(3)无反应(11/100)。以上去极化反应均可为荷包牡丹碱所阻断。GABA-去极化时膜电导增加,逆转电位值为-15——25mV。低Cl~-和高Cl~-任氏液分别使GABA-去极化反应增大和减小。10~(-4)mol/Lbaclofen不引起膜电位改变。在GABA-去极化期间,观察到大部分细胞的动作电位时程(ApD)缩短。ApD的此种变化可为baclofen所模拟,但不为荷包牡丹碱所阻断。结果提示:蟾蜍DRG神经元胞体膜有GABA_A和GABA_B受体共存,前者介导膜电位的改变,后者介导ApD的缩短。本文并联系到初级传入终末的突触前抑制的产生机制进行了讨论。     

一氧化氮和K+通道参与乙酰胆碱引起的大鼠离体输精管平滑肌细胞超极化

本文旨在探讨大鼠新鲜离体输精管平滑肌细胞中乙酰胆碱（acetylcholine,ACh）引起超极化反应的机制,采用细胞内微电极记录技术和细胞内荧光标记技术研究ACh对大鼠输精管不同走行方向平滑肌细胞的作用。用尖端含0．1％碘化吡啶（propidium iodide,PI）的记录电极标记电生理记录后的平滑肌细胞,其中37个为外层纵行细胞,17个为内层环行细胞。它们的平均静息膜电位分别为（-53．56±3．88）mV和（-51．62±4．27）mV,膜输入阻抗分别为（2245．60±372．50）MQ和（2101．50±513．50）MQ。ACh引起的膜超极化反应是浓度依赖性的,EC50为36 μmol／L。ACh引起的超极化反应可被非选择性的毒草碱（muscarinic receptor,M）受体阻断剂阿托品（atropine,1 μmol／L）和选择性的M3受体阻断剂diphenylacetoxy-N-methylpiperidine-methiodide（DAMP,100nmol/L）阻断。ACh引起的超极化还能被一氧化氮合酶抑制剂L-硝基-精氨酸甲酯（N-nitro-L-arginine methylester,L．NAME,300μmol／L）阻断,并可被ATP敏感的钾通道阻断剂glipizide（5μmol／L）或内向整流钾通道阻断剂钡离子（50μmol／L）部分阻断。Glipizide和钡离子联合使用可完全阻断ACh引起的超极化反应。上述结果表明：ACh通过作用于大鼠输精管平滑肌细胞膜上的M3受体引起超极化反应,一氧化氮、ATP敏感性钾通道和内向整流钾通道参与了ACh引起的超极化反应。     

乙酰胆碱对豚鼠心房肌和心室肌的动作电位和收缩力的不同作用

实验采用标准玻璃微电极细胞内记录技术记录心肌细胞动作电位（action potential,AP）、肌力换能器记录心肌收缩力（force contraction,Fc）,研究乙酰胆碱（acetylcholine,ACh）对离体豚鼠心房肌、心室肌的作用。结果表明,10μmol/L ACh可缩短心房肌、心室肌动作电位的时程（action potential duration,APD）。心房肌APD在给药前后分别为208.57±36.05ms及101.78±14.41ms（n=6,P<0.01）,心室肌APD在给药前后分别为286.73±36.11ms及265.16±30.06 ms（n=6,P<0.01）。心房肌动作电位的幅度（action potential amplitude,APA）也降低,给药前后分别为88.00±9.35 mV及62.62±20.50 mV（n=6,P<0.01）,而心室肌APA无明显变化。ACh还降低心房肌、心室肌的收缩力,心房肌、心室肌Fc的抑制率分别为100％（n=6,P<0.01）和37.57±2.58％（n=6,P<0.01）。ACh对心房肌、心室肌APD和Fc的抑制作用在一定范围内（1nmol/L～100μmol/L）随ACh浓度的增高而增强。用Scott法求出ACh对心房肌、心室肌APD缩短作用的KD值,分别为0.275和0.575μmol/L,对Fc抑制作用的KD值分别为0.135和0.676μmol/L。各浓度下ACh对心房肌效应与心室肌效应作组间t检验,从10nmol/L到0.1mmol/L均有显著的统计学差异。此外,10μmol/L阿托品及20mmol/L     

慢性缺氧对大鼠肺动脉内皮依赖性舒张反应及cGMP含量的影响

本实验观察了慢性缺氧对大鼠肺动脉内皮依赖性舒张反应和肺动脉内环磷酸鸟苷(cGMP)含量的影响。乙酰胆碱(ACh)和三磷酸腺苷(ATP)可使正常大鼠的离体肺动脉产生内皮依赖性舒张反应,其舒张作用不受消炎痛的影响,但被甲烯蓝完全抑制。慢性缺氧明显减低了 ACh 和 ATP 诱发的大鼠肺内和肺外动脉的内皮依赖性舒张反应。当 ACh 浓度为10~(-6)mol/L 时,缺氧组大鼠肺内和肺外动脉舒张百分数分别为对照组的61.3%和59.2%;当 ATP浓度为1.8×10~(-5)mol/L 时,缺氧组大鼠肺内和肺外动脉舒张反应分別为对照组的64.9%和55.3%。慢性缺氧也减低了硝普钠(SNP)诱发的大鼠肺动脉非内皮依赖性舒张反应。慢性缺氧显著减低了大鼠肺动脉内 cGMP 的含量。缺氧组和对照组大鼠肺动脉内 cGMP 的基础含量分别是51.9±5.7 pmol/g wet wt.(n=14)和84.9±9.7 pmol/g wet wt.(n=14),p<0.01;经 10~(-7)mol/L ACh 刺激后分别是91.4±7.3 pmol/g wet wt.(n=5)和240.8±30.6pmol/g wet wt.(n=5),p<0.01。慢性缺氧可能抑制了肺动脉平滑肌细胞胞浆中可溶性鸟苷酸环化酶,从而减低了肺动脉对内皮舒张因子和 SNP 的舒张反应性。     

豚鼠冠状动脉微动脉细胞静息膜电位的分布特性及机制

目的:观察冠状动脉微动脉细胞静息膜电位(RP)的分布特性及形成机制.方法:离体豚鼠冠状动脉微动脉(直径小于100 μm)上,应用细胞内微电极技术记录细胞RP.结果:①成功记录到112个细胞,细胞平均RP为(-65±4.2)mV,应用高斯函数拟合后细胞RP呈双峰状分布,两个峰值分别为-43和-74 mV,分别称为高和低R...     

Key role of the nicotinic receptor in neurotransmitter exocytosis in human chromaffin cells

The whole-cell secretory response evoked by acetylcholine (ACh) in human chromaffin cells was examined using a new protocol based on quickly switching from the voltage-clamp to the current-clamp (CC) configuration of the patch-clamp technique. Our experiments revealed that Ca(2+) entry through the nicotinic receptor at hyperpolarized membrane potentials contributed as much to the exocytosis (100.4 +/- 27.3 fF) evoked by 200 ms pulses of ACh, as Ca(2+) flux through voltage-dependent Ca(2+) channels at depolarized membrane potentials. The nicotinic current triggered a depolarization event with a peak at +49.3 mV and a 'plateau' phase that ended at -23.9 mV, which was blocked by 10 mumol/L mecamylamine. When a long ACh stimulus (15 s) was applied, the nicotinic current at the end of the pulse reached a value of 15.45 +/- 3.6 pA, but the membrane potential depolarization still remained at the 'plateau' stage until withdrawal of the agonist. Perfusion with 200 mumol/L Cd(2+) during the 15 s ACh pulse completely abolished the plasma membrane depolarization at the end of the pulse, indicating that Ca(2+) entry through Ca(2+) channels contributed to the membrane potential depolarization provoked by prolonged ACh pulses. These findings also reflect that voltage-dependent Ca(2+) channels were recruited by the small current flowing through the desensitized nicotinic receptor to maintain the depolarization. Finally, muscarinic receptor activation triggered a delayed exocytotic process after prolonged ACh stimulation, dependent on Ca(2+) mobilization from the endoplasmic reticulum. In summary, we show here that nicotinic and muscarinic receptors contribute to the exocytosis of neurotransmitters in human chromaffin cells, and that the nicotinic receptor plays a key role in several stages of the stimulus-secretion coupling process in these cells.     

Conduction of hyperpolarization along hamster feed arteries: augmentation by acetylcholine

The conduction of vasodilation along resistance vessels has been presumed to reflect the electrotonic spread of hyperpolarization from cell to cell along the vessel wall through gap junction channels. However, the vasomotor response to acetylcholine (ACh) encompasses greater distances than can be explained by passive decay. To investigate the underlying mechanism for this behavior, we tested the hypothesis that ACh augments the conduction of hyperpolarization. Feed arteries (n = 23; diameter, 58 +/- 4 microm; segment length, 2-8 mm) were isolated from the hamster retractor muscle, cannulated at each end, and pressurized to 75 mmHg (at 37 degrees C). Vessels were impaled with one or two dye-containing microelectrodes simultaneously (separation distance, 50 microm to 3.5 mm). Membrane potential (E(m)) (rest, approximately -30 mV) and electrical responses were similar between endothelium and smooth muscle, as predicted for robust myoendothelial coupling. Current injection (-0.8 nA, 1.5 s) evoked hyperpolarization (-10 +/- 1 mV; membrane time constant, 240 ms) that conducted along the vessel with a length constant (lambda) = 1.2 +/- 0.1 mm; spontaneous E(m) oscillations (approximately 1 Hz) decayed with lambda = 1.2 + 0.1 mm. In contrast, ACh microiontophoresis (500 nA, 500 ms, 1 microm tip) evoked hyperpolarization (-14 +/- 2 mV) that conducted with lambda = 1.9 +/- 0.1 mm, 60% further (P < 0.05) than responses evoked by purely electrical stimuli. These findings indicate that ACh augments the conduction of hyperpolarization along the vessel wall.     

非洲爪蟾卵母细胞GABAB和GABAc受体介导的电流反应

实验应用双电极电压箝技术,在具有滤泡膜的非洲爪蟾(Xenopuslaevis)卵母细胞上记录到γ-氨基丁酸(γ-aminobutyricacid,GABA)-激活电流。此GABA-激活电流的特点及有关GABA受体类型的研究和分析如下(1)在35.5%(55/155)的受检细胞外加GABA可引起一慢的浓度依赖性的外向电流。(2)GABAA受体的选择性拮抗剂bicuculline(10     

Electrophysiological responses of crayfish oocytes to biogenic amines

Intracellular recordings were made from immature, growing oocytes of the crayfish Pacifastacus leniusciulus. Oocytes had a relatively negative resting potential of -74.7+/-2.2 mV (n=26; range -53 to -90) and a mean input resistance of 0.86+/-0.19 MOmega (n=22; range 0.17-3.3). Octopamine induced a long-lasting response involving biphasic changes in input resistance, together with bi- or multiphasic changes in membrane potential. The resistance-decreasing phase involved (in different oocytes) membrane hyperpolarization, depolarization or both. The resistance-increasing phase was usually a depolarization. The hyperpolarizing form of the resistance-decreasing response, and the depolarizing resistance-increasing response reversed in polarity at membrane potentials of (respectively) -90 and -92 mV, suggesting increases and decreases in K(+) conductance underly the biphasic changes in input resistance. The threshold concentration for the response was remarkably low (>10(-12) M) and showed little or no dose-dependence over the concentration range 10(-12)-10(-6) M. Similar responses were evoked by dopamine and serotonin (at 10(-9) M), although a higher proportion of oocytes responded to octopamine and/or dopamine than to serotonin.