海南捕鸟蛛毒素-IV对大鼠背根神经节细胞钠通道的抑制影响(英文)

海南捕鸟蛛毒素 IV(HNTX IV)是从中国捕鸟蛛Seleconosmiahainana粗毒中分离得到的一种肽类神经毒素 ,在成年大鼠背根神经节 (DRG)细胞上观察了该毒素对电压门控钠通道的影响。在全细胞膜片钳条件下 ,HNTX IV能明显抑制哺乳动物神经性河豚毒敏感型 (TTX S)钠电流 ,但不影响河豚毒不敏感型 (TTX R)钠电流。HNTX IV对DRG细胞TTX S钠电流的抑制作用具有浓度依从性 ,其有效半抑制浓度 (IC50 )为 44 .6nmol/L。该毒素不影响DRG钠电流的激活与失活时间特征 ,但能导致钠通道的半数稳态失活电压向超极化方向漂移约 10 .1mV。结果表明HNTX IV是一种新型的蜘蛛毒素 ,其影响电压门控钠通道的机制可能有别于那些结合于通道位点 3来延缓钠电流失活时间特征的蜘蛛毒素如δ 澳洲漏斗网蛛毒素、μ 美洲漏斗网蛛毒素I VI等。     

虎纹捕鸟蛛神经细胞急性分离培养及其电压门控通道膜片钳

探索了虎纹捕鸟蛛(Ornithoctonus huwena)食道下神经细胞急性分离培养条件,并利用全细胞膜片钳技术对虎纹捕鸟蛛食道下神经细胞电压门控性钠、钾和钙通道的基本电生理学特性进行了研究.适合虎纹捕鸟蛛神经细胞离体培养的培养基为(g/L):葡萄糖0.7,果糖0.4,琥珀酸0.06,咪唑0.06,L-1513.7,Hepes 2.38,酵母粉2.8,乳白蛋白2.5,青霉素200 IU/ml,链霉素200 mg/ml,小牛血清15%;pH 6.8.该培养基非常适合虎纹捕鸟蛛神经节神经细胞离体培养,细胞在温度(27±2)℃的培养箱中培养2～4h,培养的细胞数目多、结构完整、贴壁效果好,细胞近似汤勺形,有一个长的单极突起,大部分细胞在10～30μm之间.全细胞模式下可以记录到钠、钾和钙三种电压门控离子通道电流.钙电流为高电压激活电流,该电流能够被NiCl2完全抑制;钾电流为瞬时钾电流和延迟整流钾电流,这两类钾电流分别被细胞外液中的4-氨基吡啶和氯化四乙胺所阻断;钠电流为TTX敏感型电流.     

海南捕鸟蛛毒素-Ⅴ分离纯化及其抑制河豚毒敏感型钠通道活性研究

经阳离子交换和反相HPLC柱层析从海南捕鸟蛛（Seleconosmia hainana）粗毒中分离到1种新的神经毒素,命记为海南捕鸟蛛毒素－Ⅴ（Hainantoxin-Ⅴ,HNTX-Ⅴ）,MALDI－TOF质谱鉴定分子量为3969.5Da。在全细胞记录膜片钳模式下,HNTX－Ⅴ对成年大鼠背根神经节（DRG）细胞河豚毒敏感型（TTX－S）钠电流有抑制作用,但对河豚鼠不敏感型（TTX－R）钠电流无明显影响。HNTX－Ⅴ对TTX－S钠电流的抑制作用具有浓度依从性,其有效半抑制浓度（IC50）为46.8nmol/L。HNTX－Ⅴ不影响TTX－S钠电流的激活相和失活相,对钠通道的激活阈值和最大激活电压也无明显改变,表明HNTX－Ⅴ影响钠通道的作用机制明显有别于δ－ACTXs等蜘蛛毒素,推测HNTX－Ⅴ很可能类似于河豚毒、Saxitoxin和μ－conotoxins,同样作用于钠通道的位点S1。     

海南捕鸟蛛毒素—Ⅳ对大鼠背根神经节细胞钠通道的抑制影响

海南捕鸟蛛毒素-Ⅳ（HNTX-Ⅳ）是从中国捕鸟蛛Seleconosmia hainana粗毒中分离得到的一种肽类神经毒素,在成年大鼠背根神经节（DRG）细胞上观察了该毒素对电压门控钠通道的影响。在全细胞膜片钳条件下,HNTX-Ⅳ能明显抑制哺乳动物神经性河豚毒敏感型（TTX-S）钠电流,但不影响河豚毒不敏感型（TTX-R）钠电流,HNTX-Ⅳ对DRG细胞TTX-S钠电流的抑制作用具有浓度依从性。其有效半抑制浓度（IC50）为44.6nmol/L。该毒素不影响DRG钠电流的激活与失活时间特征,但能导致钠通道的半数稳态失活电压向超极化方向漂移约10.1mV。结果表明HNTX-Ⅳ是一种新型的蜘蛛毒素,其影响电压门控钠通道的机制可能有别于那些结合于通道位点3来延缓钠电流失活时间特征的蜘蛛毒素如δ-澳洲漏斗网蛛毒素,μ-美洲漏斗网蛛毒素I-Ⅵ等。     

丹皮酚对NG108—15细胞电压门控K^＋,Na^＋,Ca^2＋流的抑制

利用克隆系ＮＧ１０８－１５细胞在膜片箝全细胞记录下,观察了丹皮酚对钾,钠和钙流的作用,结果表明,ＰＡ对延迟整流钾电流、钠电流、Ｔ型和Ｌ型钙电流均有明显的抑制效应,作用迅速,呈量－效关系,有相当好的可逆性。     

海南捕鸟蛛毒素-Ⅵ，一种新型的抑制昆虫电压门控钠通道失活的狼蛛神经毒素

通过阳离子交换和反相HPLC柱层析从海南捕鸟蛛（Ornithoconus hainana）粗毒中分离到一种新型的神经毒素,海南捕鸟蛛毒素-Ⅵ(HNTX-Ⅵ), 由34个氨基酸残基组成,含有6个保守的半胱氨酸残基. 运用全细胞膜片钳技术,研究了HNTX-Ⅵ对电压门控钠通道的影响.先前从海南捕鸟蛛粗毒中分离到的几种毒素,具有抑制哺乳动物钠通道激活的特性.本文研究结果表明,HNTX-Ⅵ能以类似于δ-atractoxins作用方式延缓蜚蠊背侧不成对中间(dorsal unpaired median,DUM）神经细胞的钠通道的失活,且导致钠通道稳态失活变得不完全,在预钳制电压大于-55 mV时形成不完全失活结构. HNTX-Ⅵ的这种新的功能不仅为探索钠通道的门控机制提供了有用的工具,也为开发新的安全的杀虫剂提供理论基础.     

缓激肽对背根节神经元钠通道电流的作用

目的：观察缓激肽(bradykinin,BK)对大鼠背根节神经元电压依赖性钠通道电流的作用。方法：采用全细胞膜片钳技术,记录钠通道电流。结果：缓激肽剂量依赖性(0．01～10μmol／L)增高小细胞背根节神经元诱发放电频率;缓激肽剂量依赖性(O．01～10μmol／L)增加小细胞背根节神经元的河豚毒素不敏感(TTX—resistant,TTX—R)钠电流,对TTX敏感(TTX—sensitive,TTX-S)钠电流无明显影响。结论：缓激肽引起炎性痛的机制可能与TTX-R钠通道电流有关。     

间斑寇蛛粗毒的生物学特性

近几十年来,间斑寇蛛(Latrodectus tredecimguttatus)已引起相关研究工作者的广泛关注,因为阐明其毒液中的特异性蛋白质和多肽活性成分对蜘蛛咬伤治疗具有重要的意义,且其粗毒液中的生物学活性成分在神经生物学和药物研究方面也有着潜在的应用前景。但直到现在,尽管已有不少研究报道了包括α-latrotoxin在内的几种间斑寇蛛毒性蛋白质的生物学性质和结构,但有关毒液生物学特性的系统研究的报道还很少。本研究采用解剖分离毒囊的方法从产于我国新疆的间斑寇蛛提取粗毒,并对其理化和生物学性质进行了系统的分析。定量测定结果表明,粗毒的蛋白质含量为36.99%,对小鼠和蜚蠊的LD50分别为0.39mg/kg和2.32μg/g体重。小鼠经腹腔注射粗毒后,出现呆滞、共济失调、排汗、痉挛、食欲减退、呼吸短促、睁眼困难等中毒症状,而注射生理盐水的对照小鼠活动正常。粗毒具有透明质酸酶、碱性磷酸酶、酸性磷酸酶、脱氧核糖核酸酶、乙酰胆碱酯酶、蛋白水解酶等多种水解酶的活性。10μg/ml该粗毒可以在31min±3.05min内完全抑制电刺激引起的大鼠输精管的收缩反应。6μg/ml粗毒可在25min±2.2min内完全阻断小鼠膈神经-膈肌标本的神经肌肉接头传递。膜片钳电生理实验显示,粗毒(1g/L)对蜚蠊背侧不成对中间(Dorsal unpaired median,DUM)神经元的快瞬时钾电流、钠电流、高电压激活的钙电流和大鼠背根神经节(Dorsal root ganglion,DRG)细胞延迟整流钾电流、TTX-S型钠电流、高电压激活的钙电流均无明显作用。     

雌性和雄性虎纹捕鸟蛛粗毒蛋白质含量比较分析

自然界虎纹捕鸟蛛雌蛛数量远多于雄蛛数量,为了探究雌、雄蛛粗毒的差异,用不同方法比较了单个虎纹捕鸟蛛雌、雄蛛粗毒的特征.雌蛛单次螫毒量为(26.5±2.47)μL,冻干后粗毒质量为(5.01±0.78)mg,明显高于雄蛛单次螫毒量(10.83±1.35)μL,冻干后粗毒质量(2.05±0.17)mg;用Lowry法和Bradford法测定雌蛛和雄蛛粗毒的蛋白质含量,两种方法均表明雄蛛粗毒中蛋白含量高于雌蛛.用反相高效液相色谱分离雌蛛和雄蛛粗毒蛋白,并215 nm检测色谱图,发现大部分洗脱峰重叠,而雄蛛色谱图中多两个主峰.Tricine SDS-PAGE电泳分析表明雌蛛粗毒相对分子质量小于10 kD的蛋白质含量较高;而Tris SDS-PAGE电泳分析表明雌蛛粗毒相对分子质量大于10 kD的蛋白质含量较低,基于雌蛛和雄蛛粗毒蛋白含量的差异,有必要对虎纹捕鸟蛛雌、雄蛛粗毒进行独立研究.     

虎纹捕鸟蛛毒的生物学活性鉴定

本文报道了采集广西产虎纹捕鸟蛛（Selenocosmia huwena)毒液的方法,并对粗毒进行了部分生物学活性的测定,该粗毒对小鼠和蜚蠊的LD50分钟为1．16mg/kg和300ug/g,该粗毒具有透明质酸酶,碱性磷酸酶,蛋白水解酶和脱氧核糖核酸酶活性,未测到磷脂酶A和胆碱脂酶性,通过电生理实验发现该粗毒含有阻断蟾蜍神经肌肉接头传递的毒素,并观察到当小鼠接受腹腔注射致死剂量（5mg/kg)粗毒后便迅速出现呼吸麻痹。     

我国南方捕鸟蛛一新种的生物化学鉴定(蜘蛛目,捕鸟蛛科)

采用高效液相色谱（ＨＰＬＣ）、激光解析基质辅助电离飞行时间质谱（ＭＡＩＤＩ－ＴＯＦＭＳ）和蛋白质序列分析方法,对从我国海南通什地区发现的一种捕鸟蛛与广西虎纹捕鸟蛛（Ｓｅｌｅｎｏｃｏｓｍ ｉａｈｕｗ ｅｎａ）的毒液进行了比较分析． 虽然两种蜘蛛形态十分相似,但其毒液的化学组成和主要毒素的氨基酸序列存在明显的差异,说明两种蜘蛛在进化上有同源性但分化很早．应列为不同种,特将海南发现的蜘蛛新种定名为海南捕鸟蛛,新种Ｓｅｌｅｎｏｃｏｓｍ ｉａ ｈａｉｎａｎａ ｓｐ．ｎｏｖ．     

Electrophysiological properties of human adipose tissue-derived stem cells

Human adipose tissue-derived stem cells (hASCs) represent a potentially valuable cell source for clinical therapeutic applications. The present study was designed to investigate properties of ionic channel currents present in undifferentiated hASCs and their impact on hASCs proliferation. The functional ion channels in hASCs were analyzed by whole-cell patch-clamp recording and their mRNA expression levels detected by RT-PCR. Four types of ion channels were found to be present in hASCs: most of the hASCs (73%) showed a delayed rectifier-like K(+) current (I(KDR)); Ca(2+)-activated K(+) current (I(KCa)) was detected in examined cells; a transient outward K(+) current (I(to)) was recorded in 19% of the cells; a small percentage of cells (8%) displayed a TTX-sensitive transient inward sodium current (I(Na.TTX)). RT-PCR results confirmed the presence of ion channels at the mRNA level: Kv1.1, Kv2.1, Kv1.5, Kv7.3, Kv11.1, and hEAG1, possibly encoding I(KDR); MaxiK, KCNN3, and KCNN4 for I(KCa); Kv1.4, Kv4.1, Kv4.2, and Kv4.3 for I(to) and hNE-Na for I(Na.TTX). The I(KDR) was inhibited by tetraethyl ammonium (TEA) and 4-aminopyridine (4-AP), which significantly reduced the proliferation of hASCs in a dose-dependent manner (P < 0.05), as suggested by bromodeoxyurindine (BrdU) incorporation. Other selective potassium channel blockers, including linopiridine, iberiotoxin, clotrimazole, and apamin also significantly inhibited I(KDR). TTX completely abolished I(Na.TTX). This study demonstrates for the first time that multiple functional ion channel currents such as I(KDR), I(KCa), I(to), and I(Na.TTX) are present in undifferentiated hASCs and their potential physiological function in these cells as a basic understanding for future in vitro experiments and in vivo clinical investigations.     

Comparative pharmacology and cloning of two novel arachnid sodium channels: Exploring the adaptive insensitivity of scorpion to its toxins

Scorpion toxins have been found lacking effect on Na(+) current of its own sodium channel, whereas the molecular mechanism remains mystery. In this study, the binding affinity of pharmacologically distinct scorpion toxins was found much weaker to scorpion (Buthus martensii) nerve synaptosomes than to spider (Ornithoctonus huwena) ones. The sodium channel cDNA from these two species were further cloned. The deduced proteins contain 1871 and 1987 amino acids respectively. Several key amino acid substitutions, i.e., A1610V, I1611L and S1617K, are found in IVS3-S4 constituting receptor site-3, and for receptor site-4, two residues (Leu-Pro) are inserted near IIS4 of scorpion sodium channel.     

豚鼠主动脉前庭自发性慢反应电位去极离子流的初步分析

为研究主动脉前庭自发慢反应电位的去极离充性质,利用豚鼠的离体以及心脏,常规玻璃微电极细胞内记录方法和离子通道组断剂,观测最大舒张电位（ＭＤＰ）、０相除极幅度（ＡＰＡ）、０相最大除极速度（Ｖｍａｘ）、４个自动除极速度（ＶＤＤ）、复极５０％（ＡＰＤ５０）和９０％（ＡＰＤ９０）的时间以及自发放电频率（ＲＰＦ）。结果发现：⑴０．５μｍｏｌ／Ｌ尼索地平（Ｎｉｓ）可使该慢电位的ＡＰＡ、Ｖｍａｘ、ＶＤＤ明显减小     

Na^＋,K^＋离子通道阻滞剂对离体大鼠黄体细胞...

Two ionic channel blockers, TEA and TTX, were used in the present investigation to test whether blocking of Na+, K+ ion channels would affect the production of progesterone by corpus luteum (CL) cells of rat. Both TEA (10(-3) mol/L) and TTX (10(-3) mol/L) increased progesterone production significantly after treatment. This effect of the blockers could be completely inhibited by tyrosine (Tyr). In addition, Tyr was capable of reversing the combined effect of TEA, TTX and hCG on progesterone secretion. It is suggested that the concentration gradient of Na+ and K+ across the CL cell membrane in experiments mentioned above is implicated in steroidogenesis.     

Effects of nanomolar concentration dihydroouabain on calcium current and intracellular calcium in guinea pig ventricular myocytes

The effects of nanomolar concentration of dihydroouabain (DHO) on L-type calcium current (ICa-L), TTX-sensitive calcium current (ICa(TTX)), and intracellular calcium concentration ([Ca2+]i) were investigated in guinea pig ventricular myocytes. The whole-cell patch-clamp technique was used to record ICa-L and ICa(TTX); [Ca2+]i was detected and recorded with the confocal microscopy. The nanomolar concentration of DHO increased the ICa-L, ICa(TTX), and [Ca2+]i, which could be partially inhibited by nisoldipine or TTX, but still appeared in the absence of extracellular K+ and Na+. These data suggest that DHO could increase [Ca2+]i in non-beating myocytes via stimulating the ICa-L and ICa(TTX), or perhaps triggering directly a release of intracellular calcium.     

A comparative study of the effects of tetrodotoxin and the removal of external Na+ on the resting potential: Evidence of separate pathways for the resting and excitable Na currents in squid axon

To investigate whether the Na permeability of the resting membrane is determined predominantly by the excitable Na channel, we examined the effects of tetrodotoxin (TTX) and the complete removal of external Na+ on the resting potential. In the intact squid axon bathed in K-free artificial seawater, both TTX and the removal of Na+ produced small hyperpolarizations. The effect of Na removal, however, was larger than that of TTX. In the perfused squid axon, the hyperpolarization produced by the removal of external Na+ was greatly enhanced when the internal K concentration ([K+]i) was reduced. The effect of TTX, on the other hand, was not sensitive to the [K+]i or to the membrane potential. For [K+]i = 50 mM and [K+]o = 0, the average hyperpolarization produced by TTX was 1.2 mV, while the hyperpolarization produced by Na removal was approximately 21 mV. The difference between these two effects suggests that the majority of the resting Na current passes through pathways other than the excitable Na channel.     

Function and solution structure of hainantoxin-I, a novel insect sodium channel inhibitor from the Chinese bird spider Selenocosmia hainana

Hainantoxin-I is a novel peptide toxin, purified from the venom of the Chinese bird spider Selenocosmia hainana (=Ornithoctonus hainana). It includes 33 amino acid residues with a disulfide linkage of I-IV, II-V and III-VI, assigned by partial reduction and sequence analysis. Under two-electrode voltage-clamp conditions, hainantoxin-I can block rNa(v)1.2/beta(1) and the insect sodium channel para/tipE expressed in Xenopus laevis oocytes with IC(50) values of 68+/-6 microM and 4.3+/-0.3 microM respectively. The three-dimensional solution structure of hainantoxin-I belongs to the inhibitor cystine knot structural family determined by two-dimensional (1)H nuclear magnetic resonance techniques. Structural comparison of hainantoxin-I with those of other toxins suggests that the combination of the charged residues and a vicinal hydrophobic patch should be responsible for ligand binding. This is the first report of an insect sodium channel blocker from spider venom and it provides useful information for the structure-function relationship studies of insect sodium channels.     

Ionic currents of smooth muscle cells isolated from the ctenophore Mnemiopsis

The ionic currents of smooth muscle cells isolated from the ctenophore Mnemiopsis were examined by using conventional two-electrode voltage clamp and whole-cell patch clamping methods. Several separable currents were identified. These include: (1) a transient and (2) a steady-state voltage-activated inward current; both are tetrodotoxin (TTX) and saxitoxin (STX) insensitive, partly reduced by decreasing external Ca2+ or Na+ or by addition of 5 mM Co2+, D-600 or verapamil and are totally blocked with 5 mM Cd2+; (3) an early, transient, cation-dependent, outward K+ current (IKCa/Na); (4) a transient, voltage-activated, outward K+ current provisionally identified as IA; (5) a delayed, steady-state, voltage-activated outward K+ current (IK) and (6) a late, transient, outward K+ current which is blocked by Cd2+ and evident only during long voltage pulses. Despite their phylogenic origin, most of these currents are similar to currents identified in many vertebrate smooth and cardiac muscle preparations, and other excitable cells in higher animals.