大白鼠上丘脑片深层部突触传递和LTP的研究

在大白鼠上丘脑片深层部的中层或深层给电刺激、分别在径向对应的深层或中层,记录到诱发的突触后场电位.以100Hz、1秒的强直刺激首次在上丘的深层部引出了长时程突触增强(LTP).N-甲基-D-天冬氨酸(NMDA)受体的选择性拮抗剂2-氨基-5-磷酸戊酸盐(APV)对LTP的阻断效应表明,NMDA受体不仅对上丘深层部LTP的产生有作用.而且也与LTP的维持有关.突触后场电位的幅度受APV或兴奋性氨基酸受体的非选择性拮抗剂犬尿喹啉酸(KYNA)的作用而减小,受γ-氨基丁酸(GABA)A型受体的选择性拮抗剂荷包牡丹碱(Bicu)的作用而增加,表明谷氨酸能神经递质在上丘深层部的兴奋性突触传递中起着重要作用,并且这些突触传递也受到GABA能抑制性突触的调节.     

大鼠下丘培养神经元上NMDA与GABAA受体之间的交互作用

在中枢神经系统中,不同类型的神经元的离子通道往往是通过相互作用而非独立地发挥其功能的,例如,激活一种通道能够抑制或增强另一种通道的功能.N-甲基-D-门冬氨酸受体(NMDA受体)和γ-氨基丁酸A型受体(GABAA受体)分别是中枢神经系统中重要的兴奋性和抑制性的受体.目前,在中枢神经系统中,尤其是在中枢听觉系统中,关于这...     

PSD-95 与脑缺血的关系及其调控机制研究

PSD-95(突触后密度蛋白-95)在突触后密度区含量丰富,具有复杂的结构域,与膜受体、离子通道、细胞粘附因子和信号分子等相互作用聚集成大分子复合物,在突触的可塑性、学习记忆、大脑的病理生理紊乱等起重要作用。PSD-95 与脑缺血神经元损伤和凋亡的分子机制有密切联系。脑缺血再灌注后PSD-95 在缺血侧皮层的变化表现为PSD-95 阳性细胞数的减少和细胞形态的受损改变。抑制NMDA 受体活性的治疗策略包括破坏受体本身、钙离子通道阻滞剂、破坏PSD-95/NMDAR 相互作用、破坏PSD-95/nNOS相互作用、nNOS抑制剂药物干预。已有研究发现在大鼠大脑中动脉栓塞模型中抑制PSD-95 复合体之间的相互作用可以改善脑缺血。实验性的PSD-95 抑制剂减少了短时间和长时间局部脑缺血大鼠的梗死面积、并恢复相应的运动功能治疗脑缺血。本文重点研究PSD-95 与脑缺血的关系及其调控机制。     

NMDAR/PKC通路介导基底外侧杏仁核的长时程增强

本文在大鼠杏仁核脑片上刺激外囊（external capsule,EC）,在基底外侧杏仁核（basolateral amygdala,BLA）记录场电位,观察能否在杏仁核诱导长时程增强（long—term potentiation,LTP）,并探讨杏仁核LTP形成的可能机制。应用两串间隔10min的0频率波刺激EC,可见BLA的场电位明显增强,持续时间在30min以上。EC—BLA的LTP表现为通路特异性,可被N-甲基-D-天冬氨酸受体（N-methyl—D—aspartate receptor,NMDAR）阻断剂D,L-2-氨基-5磷酸基戊酸（APV）阻断。在灌流液中加入蛋白激酶C（protein kinaseC,PKC）抑制剂chelerythrine chloride,对BLA的基础场电位和配对脉冲比率（pairedpulse ratio,PPR）没有影响;但在chelerythrine chloride存在的情况下,两串θ频率波刺激不能诱导出LTP;若于两串高频刺激10min后,在灌流液中加入chelerythrine chloride不能阻断BLA的LTP。上述结果表明,EC—BLA的LTP为NMDAR依赖性,PKC参与BLA的LTP诱导和早期维持。     

突触长时程增强形成机制的研究进展

高等动物脑内突触传递的可塑性是近30年来神经科学研究的热点,突触传递长时程增强（long-term potentiation,LTP)是神经元可塑性的反映,其形成主要与突触后机制有关。过去关于LTP机制的研究主要集中于N－甲基－D门冬氨酸（NMDA）受体的特征及该受体被激活后的细胞内级联反应,现认为脑内存在只具有NMDA受体而不具有α－氨基羟甲基恶唑丙酸（AMPA）受体的“静寂突触（silent synapse)”,这一概念的提出,使人们认识到AMPA受体在LTP表达的突触后机制中的重要作用。     

脑缺血/再灌对蒙古沙土鼠海马突触体酪氨酸磷酸化的影响

用蒙古沙土鼠双侧颈总动脉结扎（ＢＣＡＯ）前脑缺血模型,研究缺血／再灌对海马突触体蛋白酪氨酸磷酸休的影响及ＮＭＤＡ受体（ＮＲ）非竞争性拮抗剂氯胺酮（Ｋｅｔａｍｉｎｅ,ＫＴ）、Ｌ－型电压门控钙离子通道（Ｌ－ｔｙｐｅ ｖｏｌｔａｇｅ ｇａｔｅｄｃａｌｃｉｕｍ ｃｈａｎｎｅｌ,Ｌ－型ＶＧＣＣ）拮抗剂硝苯吡啶（ｎｉｆｅｄｉｐｉｎｅ,ＮＤ）及非ＮＲ拮抗６,７－二硝基喹恶啉上卫四（６,７－ｄｉ－ｎｉｔｒｏｐｕ     

“不完全氧糖剥夺”对A型氨基丁酸受体介导的抑制性突触后膜电流的增强作用

摘要: 氧糖剥夺模型作为研究脑缺血的离体模型被广泛使用,该模型模拟了局灶性脑缺血的病理变化。然而在缺血病灶中心区与正常脑组织之间的称为缺血半暗带的区域,脑血流也有程度不一的降低。为了模拟这种病理变化,我们发展了一种中等程度氧糖剥夺的离体脑片模型,该模型满足两个条件,氧气部分剥夺而葡萄糖完全剥夺。临床上通过增强A型γ-氨基丁酸受体介导的抑制活动可以阻止海马神经元的坏死,但其机制不清楚。因此我们采用全细胞膜片钳的记录方法,研究中等程度的氧糖剥夺对海马脑片CA1区神经元的A型γ-氨基丁酸受体介导的抑制性突触后膜电流(IPSCs)的影响。我们发现中等程度的氧糖剥夺使A型γ-氨基丁酸受体电流(IPSCs)的峰值增加而衰减时程延长。进一步研究发现该电流的峰值增加是由于A型γ-氨基丁酸受体－氯离子通道的电导增加所致,而与氯离子的反转电位无关。这些发现提示神经系统在中等程度脑缺血的早期阶段可以通过内稳态机制来维持兴奋性系统和抑制性系统之间的平衡。关键词: 中等程度脑缺血, A型γ-氨基丁酸受体, 抑制性突触后膜电位, 峰值     

"不完全氧糖剥夺"对A型γ-氨基丁酸受体介导的抑制性突触后膜电流的增强作用

"氧糖剥夺"模型作为研究脑缺血的离体模型被广泛使用,该模型模拟了局灶性脑缺血的主要病理变化。然而在缺血病灶核心区与正常脑组织之间称为缺血半暗带的区域,脑血流也有程度不一的降低。为了模拟这种病理变化,发展了一种"不完全氧糖剥夺"的离体脑片模型,该模型满足两个条件,灌流液里氧气部分剥夺而葡萄糖含量降低;"氧糖剥夺"可以导致谷氨酸介导的兴奋性毒性,从而引起神经细胞的坏死。而A型γ-氨基丁酸受体(GABAAR)介导的神经元抑制性活动可以对抗谷氨酸引起的兴奋性毒性,因此近年来引起广泛的研究兴趣。而谷氨酸受体和γ-氨基丁酸受体功能在缺血半暗带是否有改变尚不得而知。因此本文采用海马脑片全细胞膜片钳的记录方法,研究"不完全氧糖剥夺"对海马CA1区神经元的A型γ-氨基丁酸受体介导的抑制性突触后膜电流(IPSCs)的影响。研究发现"不完全氧糖剥夺"使GABAAR介导的IPSCs的峰值增加而衰减时程延长。进一步研究发现该电流的峰值增加是由于GABAAR-氯离子通道的电导增加所致,而与氯离子的反转电位变化无关。这些发现提示在脑缺血的缺血半暗带区域GABAAR介导的神经元抑制性活动可能是增强的,这可能是神经元面对缺血状态产生自我保护的一种内稳态机制。     

NMDA对GABAA受体的抑制作用由钙-钙调素依赖性蛋白激酶Ⅱ介导

应用制霉菌素(nystatin)穿孔全细胞记录方法,研究了N-甲基-D-门冬氨酸(NMDA)对新鲜分离的大鼠骶髓后连合核(SDCN)神经元γ-氨基丁酸(GABA)激活的全细胞电流的调控.实验结果如下:(ⅰ) 在无Mg2+及含1 μmol/L甘氨酸的标准细胞外液中,当钳制电位为-40 mV时,NMDA(100 μmol/L)可抑制GABA和muscimol (Mus)在SDCN神经元激活的全细胞电流(IGABA和IMus),且NMDA受体的竞争性拮抗剂D-2-amino-5-phosphonovalerate(APV,100 μmol/L)可完全阻断NMDA激活的电流,并可消除NMDA对IGABA的抑制作用.(ⅱ)当细胞外液中无Ca2+及待测神经元被Ca2+螯合剂BAPTA AM预处理2 h后,NMDA对IGABA的抑制作用消失;而用电压依赖性钙通道阻断剂Cd2+(10 μmol/L)或La3+(30μmol/L)预处理后,NMDA对IGABA的抑制作用仍然存在.(ⅲ) NMDA对IGABA的抑制作用可被钙-钙调素依赖性蛋白激酶Ⅱ(CaMKⅡ)的抑制剂KN-62所阻断.提示在大鼠SDCN神经元,NMDA对IGABA的抑制作用为一Ca2+依赖性的过程,这一过程的"下游"机制与细胞内CaMKⅡ有关.揭示了Ca2+和CaMKⅡ分别作为细胞内第二信使和第三信使将NMDA受体和GABAA受体的功能联系起来.     

BIOSYNTHESIS OF RIBONUCLEIC ACID IN RAT BRAIN SLICES

The incorporation of uridine into RNA in brain slices was studied. Optimal conditions for uridine incorporation were determined. The characteristics of the product suggest that de novo DNA-directcd synthesis of fairly high molecular weight material takes place. Incorporation into RNA of several areas of brain was studied. The incorporation was also studied as a function of the age of the animal. Finally, an apparent correlation was observed between the decrease in uridine incorporation with age and the increase of the enzyme uridine nucleosidase which hydrolyses uridine to uracil, a material which cannot be incorporated into RNA.     

MEASUREMENTS OF RATES OF PROTEIN SYNTHESIS IN RAT BRAIN SLICES

The use of tracer concentrations of labelled amino acids to measure incorporation in incubated slices of brain results in wide fluctuations with time in the specific activity of the precursor. Using concentrations of about 1 mm of labelled amino acid facilitates the accurate measurement of rates of synthesis. These higher precursor levels in the medium decrease the fluctuations in free amino acid specific activity due to dilution by endogenous amino acid and the production of amino acid by protein degradation, and decrease the lag in incorporation due to transport phenomena. Concentrations of 1 mm amino acid in the medium did not inhibit protein synthesis; with valine, leucine, phenylalanine, lysine and histidine, incorporation rates were similar when measured at trace concentrations and at 1 mm medium levels. The source of amino acid for protein synthesis appears to be intracellular. No evidence could be found for the preferential use of extracellular medium amino acid. The rate of incorporation of amino acids in incubated slices of rat brain was 0.087 per cent of the protein amino acid/h.     

MUSCIMOL UPTAKE, RELEASE AND BINDING IN RAT BRAIN SLICES

Abstract— The GABA analogue, muscimol, was taken up relatively inefficiently compared to GABA by slices of rat cerebral cortex at 37 C. Muscimol uptake followed saturation kinetics (K_m ImM. V_m 0.1 μmol g mini and showed an absolute dependence on sodium ions. The relative susceptibilities of muscimol uptake and GABA high affinity uptake to a variety of inhibitors, including (-)-nipecotic acid. (+)-2.4-diaminobutyric acid and arecaidine, and the stimulation of muscimol efflux by 50μM-GABA, suggest that muscimol and GABA share some common transport carriers. Since L-histidine inhibited muscimol uptake hut not GABA high affinity uptake, at least part of the observed muscimol uptake may be mediated by the 'small basic'amino acid transport system. Muscimol appeared to he taken up into nerve terminals, since uptake was inhibited by the neuronal uptake inhibitor cis -3-aminocyclohexanecarboxylic acid but not by the glial uptake inhibitor β-alanine. Muscimol efflux was stimulated in a calcium-dependent manner by an increased potassium ion concentration.
Sodium-independent binding of muscimol was observed in slices of rat cerebral cortex at 4 C. Binding could be inhibited by a variety of substances. including GABA, isoguvacine and (+)-bicuculline methochloride, which are known to inhibit the binding of muscimol to putative GABA receptors associated with synaptic membranes purified from rat brain.     

UPTAKE AND RELEASE OF D- AND L-ASPARTATE BY RAT BRAIN SLICES

D-Aspartate is accumulated by slices of adult rat cortex by a high affinity uptake which is abolished if the sodium ions in the incubation medium are replaced by choline. A small uptake of D-aspartate takes place if the sodium ions are replaced by lithium ions. It appears likely that D-aspartate shares the same transport system with L-aspartate, and that the uptake of D-aspartate is into the same osmotically-sensitive particles as those which accumulate L-aspartate. D-Aspartate is released from cerebral cortex slices by raised potassium concentrations, provided calcium is present in the perfusing buffer. Both D- and L-aspartate produce gross hyperactivity when injected intraperitoneally into immature rats. Radioactive D-aspartate may be very useful in examining the neurotransmitter role of the naturally- occurring L-aspartate e.g. in studies of the autoradiographic localization of high affinity L-aspartate accumulation, its main advantage being that, unlike L-aspartate, D-aspartate does not undergo rapid metabolism.     

THE ACTION OF TRIETHYLTIN ON THE RESPIRATION OF RAT BRAIN CORTEX SLICES

Glucose oxidation by rat brain cortex slices is inhibited by low concentrations of triethyltin and this sensitive inhibition is shown to be chloride-dependent. Pyruvate oxidation is only inhibited at high concentrations of triethyltin whether chloride is present or not. In contrast, the stimulation of both glucose and pyruvate oxidation observed with low concentrations of triethyltin prior to inhibition is chloride-dependent. The results are discussed in relation to the chloride-hydroxide exchange reaction known to be mediated across the inner mitochondrial membrane by triethyltin and other organo-metals.     

THE EFFECT OF SULFHYDRYL REAGENTS ON THE TITYUSTOXIN-INDUCED ACETYLCHOLINE RELEASE IN RAT BRAIN SLICES1

Abstract— Pre-treatment of rat brain slices with organic mercurials prevents the increased acetylcholine release induced by tityustoxin. This inhibition is reversed by dithiothreitol. N-Ethylmaleimide blocks the tityustoxin effect irreversibly. Simultaneous incubation with mercurials and toxin reveals a competition of both ligands for a membrane sulfhydryl group apparently required for tityustoxin activity.     

INHIBITION OF THE UPTAKE OF GABA AND RELATED AMINO ACIDS IN RAT BRAIN SLICES BY THE OPTICAL ISOMERS OF NIPECOTIC ACID

R(-)-Nipecotic acid was a more potent inhibitor than the S(+)-isomer of the uptake of GABA, (+)-nipecotic acid, and β-alanine in rat brain slices. (-)-Nipecotic acid was an order of magnitude more potent as an inhibitor of GABA uptake than as an inhibitor of β-alanine uptake, whereas the (+)-isomer was less selective. (–)-Nipecotic acid was a weak inhibitor of L-proline uptake and of rat brain acetylcholinesterase activity. Kinetic studies showed that both isomers of nipecotic acid were competitive inhibitors of GABA uptake when added at the same time as GABA, but non-competitive inhibitors when preincubated with the tissue for 15 min before addition of GABA. The apparent slope inhibition constants, which were not influenced by preincubation, indicated that (–)-nipecotic acid has an affinity for the carrier some 5 times higher than that for (+)-nipecotic acid. (–)-Nipecotic acid stimulated the release of preloaded radioactive GABA from rat brain slices. These observations indicate that (–)-nipecotic acid is a substrate-competitive inhibitor of GABA which combines with the GABA carrier and is taken up. (?)-Nipecotic acid and (+)-2,4-diaminobutyric acid, on the basis of their absolute structures and inhibition kinetics, are proposed to interact in a similar way with the GABA transport system.     

THE NATURE OF THE AMINO ACID POOL USED FOR PROTEIN SYNTHESIS IN RAT BRAIN SLICES

The incorporation into brain slice protein of externally provided [1-¹⁴C]valine was measured at varying levels of valine in the medium, under conditions of constant protein synthesis and equilibration of intracellular valine specific activity. The results indicate that the valine pool used for protein synthesis is not identical to the pool of total free valine. Neither does the incorporation solely occur from an extracellular pool which is in equilibrium with the incubation medium. The data are compatible with a two-site activation model in which aminoacylation of tRNA occurs at both an internal site utilizing amino acid from the intracellular pool and an external (possibly membranous) site converting extracellular valine directly to valyl-tRNA. A good fit to the experimental observations is also provided by a compartmented intracellular valine pool model.     

乙酰胆碱对培养大鼠皮层神经元兴奋性及抑制性突触电流的相反作用

在分散培养的新生大鼠皮层神经元标本上,用全细胞电压箝技术分析了自发兴奋性及抑制性突触后电流的性质并观察了乙酰胆碱对它们的影响。