腺苷对缺氧时海马神经元内游离Ca^2＋的影响

实验用Ｆｌｕｏ－３负载细胞,在激光扫描共聚焦显微镜下直接监测缺氧后分散培养的大鼠海马ＣＡ１区神经元内游离Ｃａ＾２＋浓度（［Ｃａ＾２＋］ｉ）的变化,观察腺苷对这种变化的影响并初步探讨其作用机制。结果发现,急性缺氧使海马神经元［Ｃａ＾２＋］ｉ显著升高;腺苷（１００μｍｏｌ／Ｌ）明显抑制缺氧引起的［Ｃａ＾２＋］ｉ增高,腺苷Ａ１受体拮抗剂ＣＰＴ以及Ｋ＾＋通道阻断剂４－ＡＰ和ＡＴＰ敏感性Ｋ＾＋通道阻断剂ｇｌ     

钙离子在海马脑片缺氧损伤的作用

本工作用海马脑片缺氧模型,观察了无钙、高镁人工脑脊液以及钙通道阻断剂尼莫地平对缺氧后海马脑片ＣＡ１区锥体细胞诱发群锋电位（ＰＳ０的影响。发现用无钙与高镁人工脑脊液流脑片,可显著促进脑片缺氧后ＰＳ的恢复,而尼莫地对缺氧脑片ＰＳ的则无明显促进作用。结果表明：钙离子参与海马脑片缺氧后神经元及其突触传递的损伤过程,而电压敏感性通道Ｌ亚型在缺氧损伤中可能不起主要作用。     

钙离子在海马脑片缺氧损伤中的作用

本工作用海马脑片缺氧模型,观察了无钙、高镁人工脑脊液以及钙通道阻断剂尼莫地平对缺氧后海马脑片ＣＡ１区锥体细胞诱发群锋电位（ＰＳ）的影响。发现用无钙与高镁人工脑脊液灌流脑片,可显著促进脑片缺氧后ＰＳ的恢复,而尼莫地平对缺氧脑片ＰＳ的恢复则无明显促进作用。结果表明：钙离子参与海马脑片缺氧后神经元及其突触传递的损伤过程,而电压敏感性钙通道Ｌ亚型在缺氧损伤中可能不起主要作用。     

内皮素和ATP敏感性钾通道介导缺氧所致家兔窦房结起搏细胞的电生理效应

用细胞内微电极技术研究了ＡＴＰ－敏感性钾（Ｋ_（ＡＴＰ））通道和内皮素（ｅｎｄｏｔｈｅｌｉｎ,ＥＴ）在缺氧所致窦房结起搏细胞负性频率中的作用,主要结果如下：（１）缺氧引起窦房结起搏细胞的ＲＰＦ降低和ＡＰＤ缩短,这一效应随时间延长而加重。（２）Ｋ_（ＡＴＰ）通道开放剂ｃｒｏｍａｋａｌｉｍ浓度依赖性地对窦房结起搏细胞有负性频率作用,且明显缩短ＡＰＤ_（５０）。该通道的阻断剂格列苯脲能部分阻断缺氧对起搏细胞的上述效应,表明缺氧效应中有Ｋ_（ＡＴＰ）通道的参与。（３）ＥＴ－１可显著加重缺氧所致的ＲＰＦ降低,使起搏细胞停跳时间前移;而以ＥＴ_Ａ受体阻断剂ＢＱ－１２３预处理窦房结标本后,则能有效地缓解缺氧对起搏细胞的效应,提示内源性ＥＴ－１的释放在缺氧效应中的作用。上述结果表明,缺氧所致起搏细胞的负性频率作用和ＡＰＤ缩短,与Ｋ_（ＡＴＰ）通道的激活和内源性ＥＴ－１的释放有关。     

急性分离的大鼠皮层神经细胞膜去极化激活的优降糖敏感钾单通道电流

本实验利用氰化物阻断细胞呼吸链模拟缺氧模型,采用膜片钳技术的记录方法,对急性分离的大鼠大脑皮层神经细胞膜上ＡＴＰ敏感Ｋ￣＋通道特性进行研究。结果提示：在急性分离的大鼠大脑皮层神经细胞膜丢极化激活时,可记录到一类被优降糖（ＡＴＰ敏感钾通道阻断剂）阻断的钾通道,可能属新型ＡＴＰ敏感Ｋ￣＋通道。     

蛋白激酶C对大鼠缺血海马突触体谷氨酸摄取的调控作用

采用大鼠海马脑片体外缺血模型,观察海马突触体内蛋白激酶Ｃ（ＰＫＣ）活性的变化,以及这种变化对突触体谷氨酸（ＧＬＵ）摄取的影响。结果显示：海马脑片体外“缺血”１０ｍｉｎ,其突触体内ＰＫＣ活性基本不变,而缺血３０ｍｉｎ,突触体内ＰＫＣ活性显著上升（Ｐ＜０．０１,ｎ＝６）;非Ｎ－甲基－Ｄ－天门冬氨酸（ＮＭＤＡ）受体拮抗剂ＤＮＱＸ有效地抑制ＰＫＣ活性的同时,可降低胞外ＧＬＵ的堆积,而ＮＭＤＡ受体阻断剂ＡＰ＿５无作用。进一步实验证明,ＰＫＣ激动剂ＰＤＢ浓度依赖性地抑制突触体对３Ｈ－ＧＬＵ的摄取（ＩＣ５０＝１３１±１０μｍｏｌ／Ｌ）,此抑制作用可由ＰＫＣ抑制剂Ｈ－７（１００μｍｏｌ／Ｌ）抵消。提示脑缺血诱发ＧＬＵ堆积的作用机理可能是：脑缺血引发钙内流导致ＧＬＵ过量释放,ＧＬＵ又通过突触前非ＮＭＤＡ受体激活ＰＫＣ,抑制其自身摄取,正反馈性加重胞外ＧＬＵ的堆积。     

大鼠胰腺β细胞离子通道的一些特性

实验以单个Ｗｉｓｔａｒ大鼠胰腺β细胞为对象,用穿孔膜片箝和细胞贴附式记录技术研究ＡＴＰ敏感Ｋ＾＋通道（ＫＡＴＰ）、延迟整流型Ｋ＾＋通道（ＫＤＲ）、Ｃａ＾２＋通道和Ｎａ＾＋通道的有关特性。结果表明：⑴ＫＡＴＰ通道的内流电导约６５ｐＳ,外流电导约３１ｐＳ,反转电位在－６０ｍＶ左右;⑵ＫＤＲ通道在延迟２０ｍｓ后达到最大激活,ＫＤＲ电流约为ＫＡＴＰ的１／３;⑶钙电流在０ｍＶ左右达到４０－６０ｐＡ的峰值,Ｌ     

神经肽AVP（4—8）激活大鼠海马突触膜上的G蛋白偶联受体

精氨酸加压素（ＡＶＰ）的Ｃ端内片段,ＡＶＰ（４－８）,具有增强记忆的功能,它在大鼠脑内引发一系列的生理和生化变化。ＧＴＰ－结合调节蛋白（Ｇ蛋白）介导多数神经肽和神经调质的细胞内生理生化反应,放射性受体结合实验显示,在海马突触膜上存在ＡＶＰ（４－８）的特异性结合位点。ＡＶＰ（４－８）在海马突触膜上的结合能够进一步刺激ＧＴＰγＳ结合并可被ＡＶＰ（４－８）的受体拮抗剂ＺＤＣ（Ｃ）ＰＲ所逆转。从以上实验结     

内皮素对家兔窦房结起搏细胞电活动的影响

本文用细胞内微电极技术观察了ＥＴ－１对家兔窦房结起搏细胞电生理活动的影响。所得结果如下：（１）在以ＥＴ－１作表面灌流时,起搏细胞的４相自动去极化的速度（ＶＤＤ）显著减慢,且呈浓度依赖性,结果导致起搏细胞的自发放电频率（ＲＰＦ）降低。（２）由ＥＴ－１引起的ＶＤＤ和ＲＰＦ下降,可由事先投用ＥＴ＿Ａ＾受体选择性阻断剂ＢＱ－１２３（２０,１００μｇ／Ｌ）所阻断。这一结果有力提示,ＥＴ－１对起搏细胞的电生理效应是由ＥＴ＿Ａ受体亚型介导的。（３）事先投用Ｋ＿（ＡＴＰ）通道阻断剂格列苯脲（１０μｍｏｌ／Ｌ）,可完全消除ＥＴ－１对起搏细胞的负性频率作用。根据上述结果,似可认为,ＥＴ－１与ＥＴ＿Ａ受体的结合可激活Ｋ＿（ＡＴＰ）通道,致使Ｋ￣＋电流增加和起搏细胞的ＶＤＤ减慢。     

ATP敏感性钾通道在心血管系统中的作用

ＡＴＰ敏感性钾通道对Ｋ＾＋有较高的选择性,且有相当高的电导。磺酰脲类药物对ＡＴＰ敏感性钾通道有特异的抑制作用,而一些开放剂对其有激活作用。缺血或其它代谢抑制时,ＡＴＰ浓度下降,腺苷产生产增加,两者激活ＡＴＰ敏感性钾通道,对心肌缺血再灌注损伤起保持作用;ＡＴＰ敏感性钾通道开放剂对高血压有一定的治疗效用。     

Role of K(ATP)(+) channels and adenosine in the control of coronary blood flow during exercise.

The present study was designed to examine the role of ATP-sensitive potassium (K(ATP)(+)) channels during exercise and to test the hypothesis that adenosine increases to compensate for the loss of K(ATP)(+) channel function and adenosine inhibition produced by glibenclamide. Graded treadmill exercise was used to increase myocardial O(2) consumption in dogs before and during K(ATP)(+) channel blockade with glibenclamide (1 mg/kg iv), which also blocks adenosine mediated coronary vasodilation. Cardiac interstitial adenosine concentration was estimated from arterial and coronary venous values by using a previously tested mathematical model (Kroll K and Stepp DW. Am J Physiol Heart Circ Physiol 270: H1469-H1483, 1996). Coronary venous O(2) tension was used as an index of the balance between O(2) delivery and myocardial O(2) consumption. During control exercise, myocardial O(2) consumption increased approximately 4-fold, and coronary venous O(2) tension fell from 19 to 14 Torr. After K(ATP)(+) channel blockade, coronary venous O(2) tension was decreased below control vehicle values at rest and during exercise. However, during exercise with glibenclamide, the slope of the line of coronary venous O(2) tension vs. myocardial O(2) consumption was the same as during control exercise. Estimated interstitial adenosine concentration with glibenclamide was not different from control vehicle and was well below the level necessary to overcome the 10-fold shift in the adenosine dose-response curve due to glibenclamide. In conclusion, K(ATP)(+) channel blockade decreases the balance between resting coronary O(2) delivery and myocardial O(2) consumption, but K(ATP)(+) channels are not required for the increase in coronary blood flow during exercise. Furthermore, interstitial adenosine concentration does not increase to compensate for the loss of K(ATP)(+) channel function.     

Mitochondrial K(ATP) channels and sarcoplasmic reticulum influence cardiac force development under anoxia in the Amazonian armored catfish Liposarcus pardalis

The contribution of alterations in mitochondrial K(ATP) channel activity and the sarcoplasmic reticulum (SR) to anaerobic cardiac function in the anoxia tolerant armored catfish Liposarcus pardalis were assessed. K(ATP) channels contribute to hypoxic cardioprotection in mammals, but little is known of their action in more hypoxia tolerant animals. Anoxia resulted in a decrease in force in isometrically contracting ventricle strips to approximately 40% of the pre-anoxic level. This was maintained for at least 2 h. Upon reoxygenation, hearts recovered to the same level as control preparations. Treatment with 5-hydroxydecanoic acid (5HD), a specific mitochondrial K(ATP) blocker significantly increased force in preparations during anoxia and caused hypercontracture at reoxygenation. Ryanodine, a specific inhibitor of SR function, significantly increased force loss in ventricle preparations under anoxia. Results show that mitochondrial K(ATP) channel activity and SR function are important in anaerobic and post-anaerobic contractility in armored catfish heart.     

Inhibitors of ATP-sensitive potassium channels stimulate intestinal cholecystokinin secretion

Recently, a role for adenosine 5′-triphosphate(ATP)-sensitive potassium channels in the regulation of cholecystokinin (CCK) secretion has been described in STC-1 cells, an intestinal CCK-secreting cell line. To examine whether a similiar mechanism might participate in the regulation of hormone secretion from native CCK cells, the effects of two established inhibitors of ATP-sensitive potassium channels (e.g. glucose, disopyramide) were examined on CCK release from dispersed murine intestinal cells. Both glucose and disopyramide were found to stimulate CCK secretion. Furthermore, CCK release induced by glucose was inhibited by the calcium channel blocker diltiazem. It is concluded that, ATP-sensitive potassium channels may play a role in the regulation of intestinal CCK secretion.     

颈动脉内注射腺苷对去缓冲神经大鼠最后区神经元放电的影响

在45只切断双侧缓冲神经的SpragueDawley大鼠,应用细胞外记录方法,观察了颈动脉内注射腺苷对76个最后区(AP)神经元自发放电活动的影响。所得结果如下:(1)在记录到的42个自发放电单位中,颈动脉内注射腺苷(25μg/kg)引起其中29个单位的放电频率由626±075下降至474±076spikes/s(P<001),6个单位放电频率由413±077增加至472±083spikes/s(P<005),另外7个单位放电频率无明显变化,而血压和心率在实验中无变化;(2)在应用非选择性腺苷受体拮抗剂8苯茶碱(8phenyltheophylline,15μg/kg)的10个单位,腺苷对放电的抑制效应可被完全阻断;(3)应用选择性腺苷A1受体拮抗剂8环戊1,3二丙基黄嘌呤(8cyclopentyl1,3dipropylxanthine,50μg/kg)亦可有效地阻断腺苷对12个单位的抑制效应;(4)应用ATP敏感性钾通道阻断剂格列苯脲(500μg/kg)的12个单位,腺苷的上述效应也被消除。以上结果提示,腺苷对AP区神经元自发放电有抑制作用,而此作用与A1受体介导的ATP敏感性钾通道开放有关。     

Reversible decreases in ATP and PCr concentrations in anoxic turtle brain

A hallmark of anoxia tolerance in western painted turtles is relative constancy of tissue adenylate concentrations during periods of oxygen limitation. During anoxia heart and brain intracellular compartments become more acidic and cellular energy demands are met by anaerobic glycolysis. Because changes in adenylates and pH during anoxic stress could represent important signals triggering metabolic and ion channel down-regulation we measured PCr, ATP and intracellular pH in turtle brain sheets throughout a 3-h anoxic-re-oxygenation transition with ³¹P NMR. Within 30 min of anoxia, PCr levels decrease 40% and remain at this level during anoxia. A different profile is observed for ATP, with a statistically significant decrease of 23% occurring gradually during 110 min of anoxic perfusion. Intracellular pH decreases significantly with the onset of anoxia, from 7.2 to 6.6 within 50 min. Upon re-oxygenation PCr, ATP and intracellular pH recover to pre-anoxic levels within 60 min. This is the first demonstration of a sustained reversible decrease in ATP levels with anoxia in turtle brain. The observed changes in pH and adenylates, and a probable concomitant increase in adenosine, may represent important metabolic signals during anoxia.     

Involvement of K(+) channels in the inhibitory effects of adenosine on anoxia-induced [Ca(2+) ](i) increase in cultured rat hippocampal CA1 neurons.

Changes in intracellular free Ca(2+) concentration ([Ca(2+)](i)) in cultured hippocampal CA1 neurons isolated from newborn rats were measured by a confocal laser scanning microscope, using the Ca(2+) indicator Fluo-3. The results showed that exogenous adenosine (100 microM) significantly attenuated the increase of neuronal [Ca(2+)](i) induced by acute anoxia. This effect of adenosine could be suppressed by the adenosine A1 receptor antagonist 8-cyclopentyltheophylline. Moreover, potassium channel blockers, aminopyridine, and glipizide could also block the inhibitory role of adenosine, but tetraethylammonium had no effect. These results suggest that adenosine may activate 4-AP or ATP-sensitive potassium channels via an A1-receptor-mediated mechanism and consequently inhibit anoxia-induced [Ca(2+)](i) elevation in hippocampal neurons.