低压低氧暴露对大鼠空间记忆及海马谷氨酸受体表达的影响*

目的:观察低压低氧暴露对成年大鼠空间记忆及谷氨酸递质系统受体(AMPA,NMDA)的影响。方法:SD大鼠随机分成两组,对照组和低氧组(n=10),经过5天的Moriis水迷宫训练,分别接受常压和低压低氧暴露7天,再通过Morris水迷宫观察暴露后的空间记忆,western blot检测GluR1,NMDA受体表达情况。结果:水迷宫结果显示低压低氧暴露后,平均逃脱潜伏期增长,平台搜索能力下降。Western blot结果显示磷酸化的GLUR1受体和NMDA受体水平升高。结论:低压低氧暴露可诱导大鼠的空间记忆损伤,其机制可能与谷氨酸递质系统紊乱造成的兴奋性中毒有关。     

大鼠脑发育不同时期学习记忆的变化及与NMDA受体通道动力 …

目的：研究大鼠脑发育不同时期学习记忆的变化及与ＮＭＤＡ受体通道动力学特性的关系。方法：采用学习记忆行为和离子通道动力学特性测定相结合的方法。结果：在爬杆主动回避反应中,发育早期大鼠习得和保持能力场明显强于成年大鼠。同时,发育早期大鼠训练后ＮＭ受体ｐＳ导电,而且３５ＰＳ通道开放时间和开放概率增加,３５ＰＳ通道长开放成份增多,有长ｃｌｕｓｔｅｒ开放而砀上大鼠２０Ｓ,３５ＰＳ通道关闭时间常数明显长于年龄     

高原鼠兔、高原鼢鼠肠道菌群对低压低氧环境下大鼠海马组织Aβ、Tau及BDNF蛋白的影响

为了探究暴露低压低氧不同时间以及移植高原鼠兔、高原鼢鼠肠道菌群后暴露低压低氧环境是否会影响SD大鼠海马组织β淀粉样蛋白(beta-amyloid protein, Aβ)、tau及脑源性神经营养因子(brain-derived neurotrophic factor, BDNF)的表达水平,首先将SD大鼠随机分为常氧组、低压低氧组和低压低氧处理组,低压低氧组根据暴露低压低氧时间又分为第1、3、7、15、28天组,低压低氧处理组则根据处理因素分为低压低氧对照组、低压低氧+抗生素处理组、低压低氧+抗生素+鼢鼠菌处理组、低压低氧+抗生素+鼠兔菌处理组、低压低氧+抗生素+SD大鼠菌处理组(10只/组),共11组;然后采用尼氏染色观察常氧组和低压低氧组海马组织神经细胞的形态变化,采用Western-blot检测各组Aβ、tau及BDNF蛋白表达水平。结果显示,与常氧组相比,低压低氧组从第3天开始海马组织CA1区的神经细胞排列疏松紊乱,细胞核固缩明显,并具有时间依赖性;Aβ、tau蛋白水平分别从低压低氧暴露第7天、3天开始显著升高,并随低压低氧暴露时间的延长进一步升高,其中以tau蛋白升高尤为明显...     

N-甲基-D-门冬氨酸受体通道复合体

N-甲基-D门冬氨酸(NMDA)受体通道复合体不同于一般的递质门控或电压门控的离子通道,而是兼有递质门控与电压门控双重特征。该受体通道有四种以上不同的电导水平,因而可能是多个受体亚型结合的一个复合的分子实体。NMDA受体通道的开放可引起钠、钾、钙离子内流。已经发现NMDA受体通道与长时程突触增强,癫痫等脑活动有关。     

白细胞介素-6对新生大鼠海马神经元电压依赖离子通道和NMDA电流的影响

目的: 研究白细胞介素-6对海马神经元电压依赖离子通道和NMDA电流的影响.方法: 应用全细胞膜片钳技术观察IL-6对电压依赖性钠通道电流(INa),延迟整流性钾通道电流(IK),电压依赖性钙通道电流(ICa),NMDA(N-methyl-D-aspartate)受体通道电流的影响.结果: 50 ng/ml IL-6作用24 h后IK 和ICa明显减小,Cm明显增大.50,500 ng/ml时减小NMDA电流.结论: IL-6通过作用于电压依赖钾通道,钙离子通道及NMDA通道影响神经元功能.     

NMDA受体激活引起的突触活动对Wnt非经典通路的影响

目的探讨NMDA受体激活引起的突触活动诱导Wnt非经典通路的活化。方法构建C57BL/6J胎鼠大脑皮层神经元原代培养体系,用NMDA处理神经元细胞,并结合Western blotting、双免疫荧光染色等技术,检测神经元细胞内Wnt非经典通路的相关蛋白的变化。结果免疫荧光染色显示成功建立了C57BL/6J胎鼠大脑皮层神经元体外培养体系,原代神经元细胞在体外培养10d生长良好,且纯度达90%;体外培养的神经元细胞内存在Wnt5a神经递质,经NMDA的刺激,发现Wnt非经典通路的两个标志性蛋白CaMKII和JNK的磷酸化水平显著增加,且Wnt非经典通路的一种受体Frizzled-5的蛋白表达水平也显著增加。进一步的研究显示,用NMDA竞争性抑制剂DAP5能够阻断NMDA引起的CaMKII和JNK蛋白的磷酸化水平的提高。结论 NMDA受体的激活会诱导Wnt非经典通路的活化。     

白细胞介素-6对新生大鼠海马神经元电压依赖离子通道和NMDA电流的影响

目的 :研究白细胞介素 6对海马神经元电压依赖离子通道和NMDA电流的影响。方法 :应用全细胞膜片钳技术观察IL 6对电压依赖性钠通道电流 (INa) ,延迟整流性钾通道电流 (IK) ,电压依赖性钙通道电流 (ICa) ,NMDA(N methyl D aspartate)受体通道电流的影响。结果 :5 0ng/mlIL 6作用 2 4h后IK和ICa明显减小 ,Cm明显增大。 5 0 ,5 0 0ng/ml时减小NMDA电流。结论 :IL 6通过作用于电压依赖钾通道 ,钙离子通道及NMDA通道影响神经元功能。     

NMDA受体通道的结构与功能

近来用分子克隆方法对N-甲基-门冬氨酸受体(NMDA受体)通道的分子结构进行了广泛的研究.这些研究清楚地显示了NMDA受体通道的分子多样性,为NMDA受体通道的在体功能多样性提供了基础.已获得的克隆为研究这些受体通道分布和生理作用提供了有价值的工具.     

NMDA受体通道参与大鼠脊髓背角C纤维诱发电位LTP的表达

以往研究表明,激动NMDA受体是引起海马长时程增强(LTP)的必备条件,而LTP的表达主要与AMPA受体的磷酸化及其受体组装到突触后膜有关.但是,近年来有研究表明NMDA受体通道也参与了LTP的表达.为探讨NMDA受体通道是否参与了脊髓背角C纤维诱发电位LTP的表达,诱导LTP后,分别静脉或脊髓局部给予NMDA受体拮抗剂MK801或APV,观察其作用.发现静脉注射非竞争性NMDA受体MK801(0.1mg/kg)对脊髓LTP无影响,注射0.5mg/kg显著抑制LTP,但是当剂量增高到1.0mg/kg时,抑制作用并未进一步增大.脊髓局部给予MK801也能抑制脊髓背角LTP.为验证上述结果,使用了竞争性NMDA受体拮抗剂APⅤ.结果显示,脊髓局部给予50μmol/LAPⅤ对LTP无影响,100μmol/L对LTP有显著的抑制作用,当浓度升至200μmol/L时,抑制作用并未见进一步增强.因此认为,NMDA受体通道部分地参与了脊髓背角C纤维诱发电位LTP的表达.     

慢性间歇低压低氧暴露对小鼠空间记忆及海马谷氨酸受体磷酸化 水平的影响

目的:观察慢性间歇低压低氧暴露对成年C57小鼠认知功能、海马区p-Glu R-831、845位点蛋白表达以及海马区突触囊泡释放的影响。方法:雄性C57小鼠,随机分为对照组(n=16)与暴露组(n=16)。暴露组给予每天6 h 5000 m低压低氧暴露,持续4w;对照组无低压低氧暴露。两组小鼠其他饲养条件一致。利用Morris水迷宫实验检测每组小鼠空间记忆能力;免疫印迹实验检测Glu R1蛋白ser831和ser845位点磷酸化水平变化;透射电镜实验观察低氧对突触囊泡的影响。结果:(1)水迷宫结果显示慢性间歇低压低氧暴露后,暴露组平均逃脱潜伏期(17.6±1.69 s)显著低于对照组(27.3±1.45 s),暴露组小鼠平台搜索能力提升;(2)免疫印迹结果显示,暴露组小鼠海马Glu R1蛋白ser831和ser845位点磷酸化水平显著高于对照组小鼠;(3)透射电镜结果显示,暴露组小鼠海马区突触囊泡数目显著多于对照组,且差异有统计学意义。结论:慢性间歇低压低氧暴露可以显著提升C57小鼠空间认知功能,其机制可能是通过增加Glu R1蛋白ser831和ser845位点磷酸化水平,并增加突触结构内囊泡数目。     

丹参酮ⅡA 预防慢性缺氧大鼠认知功能障碍的电生理机制

目的:探讨丹参酮ⅡA(TⅡA)预防慢性缺氧大鼠认知功能障碍的电生理机制。方法:将18只雄性SD大鼠(200-250 g)随机分为对照组、模型组(Model组)、TⅡA(10mg/kg.d)治疗组(TⅡA组)。复制慢性缺氧大鼠认知功能障碍模型,并给予相应治疗,在脑片水平运用膜片钳技术检测海马CA1区的LTP变化,并检测海马CA1区锥体细胞的兴奋性变化。结果:(1)给予高频强直刺激(HFS)后各组兴奋性突出后电位(fEPSP)斜率均显著增加,即均可诱发LTP并持续1h以上,但模型组LTP较对照组显著减弱(P<0.05),TⅡA治疗组LTP较模型组明显增强(P<0.05);(2)慢性缺氧使海马CA1锥体细胞放电所需的刺激电流幅度显著增加、阈电位升高、兴奋性降低,同样刺激强度条件下动作电位数量减少,TⅡA干预可明显减轻慢性缺氧对海马CA1锥体细胞的上述抑制。结论:TⅡA可能是通过维持海马CA1锥体细胞的兴奋性、维持海马的突出可塑性减轻慢性缺氧对认知功能的损害。     

兴奋性氨基酸加强高原低氧大鼠下丘脑前生长抑素原mRNA的表达

目的和方法：应用大鼠高原低氧模型及原位杂交技术和氨基酸测定法,研究下丘脑前生长抑素原（ＰＰＳ）ｍＲＮＡ表达和谷氨酸（Ｇｌｕ）、天门冬氨酸（Ａｓｐ）含量的变化。结果：高原低氧组大鼠下丘脑Ｇｌｕ和Ａｓｐ的含量明显增多,室周核、室旁核、弓状核ＰＰＳ－ｍＲＮＡ阳性神经元数目显著增加;而ＮＭＤＡ受体拮抗抗剂氯铵酮,虽然对Ｇｌｕ和Ａｓｐ含量无明显影响,但可使高原低氧大鼠下丘脑ＰＰＳ－ｍＲＮＡ阳性神经元数目减少     

Hypobaric hypoxia regulates iron metabolism in rats

Intermittent hypobaric hypoxia can produce a protective effect on both the nervous system and non-nervous system tissues. Intermittent hypobaric hypoxia preconditioning has been shown to protect rats from cardiac ischemia-reperfusion injury by decreasing cardiac iron levels and reactive oxygen species (ROS) production, thereby decreasing oxidative stress to achieve protection. However, the specific mechanism underlying the protective effect of hypobaric hypoxia is unclear. To shed light on this phenomenon, we subjected Sprague-Dawley rats to hypobaric hypoxic preconditioning (8 hours/day). The treatment was continued for 4 weeks. We then measured the iron content in the heart, liver, spleen, and kidney. The iron levels in all of the assessed tissues decreased significantly after hypobaric hypoxia treatment, corroborating previous results that hypobaric hypoxia may produce its protective effect by decreasing ROS production by limiting the levels of catalytic iron in the tissue. We next assessed the expression levels of several proteins involved in iron metabolism (transferrin receptor, L-ferritin, and ferroportin1 [FPN1]). The increased transferrin receptor and decreased L-ferritin levels after hypobaric hypoxia were indicative of a low-iron phenotype, while FPN1 levels remained unchanged. We also examined hepcidin, transmembrane serine proteases 6 (TMPRSS6), erythroferrone (ERFE), and erythropoietin (EPO) levels, all of which play a role in the regulation of systemic iron metabolism. The expression of hepcidin decreased significantly after hypobaric hypoxia treatment, whereas the expression of TMPRSS6 and ERFE and EPO increased sharply. Finally, we measured serum iron and total iron binding capacity in the serum, as well as red blood cell count, mean corpuscular volume, hematocrit, red blood cell distribution width SD, and red blood cell distribution width CV. As expected, all of these values increased after the hypobaric hypoxia treatment. Taken together, our results show that hypobaric hypoxia can stimulate erythropoiesis, which systemically draws iron away from nonhematopoietic tissue through decreased hepcidin levels.     

Different capacities of various NMDA receptor antagonists to prevent ischemia-induced neurodegeneration in human cultured NT2 neurons

In the present study, human NT2 neurons obtained from embryonic teratocarcinoma (NT2) cells were established as human in-vitro model to investigate the mechanisms associated with hypoxia/ischemia-induced neuronal injury. NT2 neurons express functional NMDA receptors that are of particular significance for hypoxia/ischemia-related neuronal damage. In patch-clamp recordings under normoxic conditions, NMDA (plus 10 microM glycine)-induced inward currents (EC(50)=43.7 microM) were distinctly antagonized by memantine, a blocker of the receptor channel, but only slightly by 5,7-dichlorokynurenic acid (DCKA), a glycine(B) binding site antagonist. Immunohistochemistry demonstrated that the NT2 neurons are mostly GABAergic; they predominantly express the NMDA receptor subunits NR2B and NR2C, and lower levels of NR1 and, particularly, of NR2A. Upon glucose and oxygen deprivation for 3h the loss of cell viability measured directly after 3h was higher than after application of either hypoxia or aglycemia as assessed by propidium iodide flow cytometry. Ischemic conditions significantly reduced the NMDA responses associated with a decrease in EC(50) and decreased mitochondrial membrane potential as detected by JC-1 flow cytometry. Memantine (50 microM) and CGS19755 (a competitive NMDA receptor antagonist; 10 microM) reduced ischemia-induced cell death, in contrast to DCKA (10 microM). In conclusion, in the present human in-vitro model for studying the molecular mechanisms associated with ischemic injury, neuroprotection could be achieved with NMDA receptor antagonists but not with a glycine(B) binding site antagonist. Accordingly, glycine antagonists might not represent an optimal therapeutic strategy for preventing ischemic neuronal damage in contrast to NMDA receptor antagonists like memantine.     

NMDA receptor modification in the fetal guinea pig brain during hypoxia

The effect of maternal hypoxia on the modification of the fetal brain cell membrane N-methyl-d-aspartate (NMDA) receptor and its modulatory sites was investigated. Experiments were conducted in pregnant guinea pigs of 60 days of gestation. Guinea pig fetuses were exposed to maternai hypoxia (FiO₂=7%) for 60 minutes. Tissue hypoxia in the fetal brain was documented biochemically by decreased levels of ATP and phosphocreatine (91.3% and 88.6% lower than normoxia, respectively). MK-801 binding characteristics (Bmax = number of receptors, Kd = affinity of receptor) were used as an index of NMDA receptor modification. P2 membrane fraction was prepared from the cortex of normoxic and hypoxic fetal brain and washed thoroughly before carrying out the binding assay. In hypoxic brains, Bmax decreased from the normoxic control level 0.79±0.03 pmol/mg protein to 0.58±0.03 pmol/mg protein (P<0.005) and Kd value decreased (increased affinity) from 8.54±0.27 nM to 4.01±0.23 nM (P<0.005) respectively. The MK-801 binding in the absence of added glutamate and glycine in hypoxic brain was 100% higher as compared to controls, indicating an increased sensitivity of the NMDA receptor to activation. The spermine dependent maximum activation of the NMDA receptor increased to 44% in the hypoxic animals as compared to 25% in controls. The Mg²⁺ response of the NMDA receptor was not affected by hypoxia. The increased affinity and increased basal activation (tone) of the NMDA receptor during hypoxia, as well as its increased activation by spermine, would hyperstimulate the NMDA receptor-ion channel complex function which could increase the susceptibility of the fetal brain to hypoxia. The results of this study indicate that hypoxia causes differential and selective modification of specific sites (recognition, co-activator, and modulatory) of the NMDA receptor ion channel complex. The hypoxia-induced modification of the NMDA receptor modulatory sites appears to be the potential mechanism of neuroexcitotoxicity.     

Open channel block of NMDA receptor responses evoked by tricyclic antidepressants

The action of desipramine (DMI) and promazine on the response of mouse hippocampal neurons to the excitatory amino acid N-methyl-D-aspartic acid (NMDA) was investigated using whole-cell and single-channel recording. DMI at 20-50 microM was a potent, selective antagonist of responses to NMDA but not kainate or quisqualate. At -60 mV, the Kd for DMI block of responses to NMDA was 10 microM. The potency of DMI as an NMDA antagonist was highly voltage-dependent and behaved as though the Kd increased e-fold per 36 mV depolarization, reflecting an increase in the dissociation rate constant. Prior block of NMDA receptors with Mg2+ prevented binding of DMI, suggesting an action in the open channel. Single-channel analysis showed a decrease in the open time and burst length distributions, consistent with binding of DMI to open channels. We suggest that the action of DMI on NMDA receptor channels is similar to that of MK-801 and does not reflect binding to other domains, such as the regulatory sites for Zn2+ and glycine.     

Maturation-dependent reduced responsiveness of intracellular free Ca2+ ions to repeated stimulation by N-methyl-D-aspartate in cultured rat cortical neurons

In contrast to other ionotropic glutamate receptors, N-methyl-d-aspartate (NMDA) receptor channels are rather stable after the simulation. Brief exposure to NMDA at 50 microM rapidly increased the fluorescence intensity for increased intracellular free Ca(2+) levels in a reversible- and concentration-dependent manner in rat cortical neurons cultured for 3-15 days in vitro (DIV), while EC(50) values were significantly decreased in proportion to cellular maturation from 3 to 15 DIV. Although a constant increase was persistently seen in the fluorescence throughout the sustained exposure to NMDA for 60 min irrespective of the cell maturation from 3 to 15 DIV, the second brief exposure for 5 min resulted in a less efficient increase in the fluorescence than that found after the first brief exposure for 5 min in a manner dependent on intervals between the two repetitive brief exposures. In vitro maturation significantly shortened the interval required for the reduced responsiveness to the second brief exposure, while in immature neurons prolonged intervals were required for the reduced responsiveness to the second brief exposure to NMDA. Moreover, brief exposure to NMDA led to a marked decrease in immunoreactivity to extracellular loop of NR1 subunit in cultured neurons not permeabilized in proportion to the time after washing. These results suggest that cellular maturation would facilitate the desensitization process to repeated stimulation by NMDA, without markedly affecting that to sustained stimulation, through a mechanism related to the decreased number of NMDA receptors expressed at cell surfaces in cultured rat cortical neurons.     

Hypoxia increases calcium flux through cortical neuron glutamate receptors via protein kinase C

The effects of 30 s to 10 min hypoxia (PO2-10 mmHg) on glutamate receptor activity were studied in murine cortical neurons. Receptor activity was assessed as a rise in intracellular calcium concentration ([Ca2+]i) following a 10 s application of 1 mm glutamate or 100 micro mN-methy-d-aspartate (NMDA) in the presence of 0.1 mm Mg2+ and 10 micro m glycine. Change in [Ca2+]i elicited by glutamate increased 26% (n = 192, p < 0.001) and that to NMDA by 74% (n = 9, p < 0.01) during a 100-s period of hypoxia. After 10 min hypoxia, responses to glutamate were 62% smaller than those in normoxia, with increased basal intracellular [Ca2+]i predicting reduced receptor activity. When neurons were exposed to NMDA after 10 min of hypoxia, [Ca2+]i increases were 12% smaller than after 100 s hypoxia, but still 53% larger than in oxygenated neurons (n = 9, p = 0.01). Neurons expressed relatively similar amounts of NR2A, -B, -C, and -D subunits. The phosphorylation of NMDA NR1 subunits increased during hypoxia. Pre-treatment of neurons with a protein kinase C (PKC) inhibitor (chelerythrine, 10 micro m) prevented increases in N-methy-d-aspartate receptor (NMDAR) activity during hypoxia and reduced the phosphorylation of NR1 subunits. These results suggest that enhancement of glutamate receptor activity during the first minutes of hypoxia is mediated by phosphorylation of NMDARs by PKC and that other mechanisms, possibly involving intracellular calcium, limit glutamate receptor-mediated calcium influx during longer periods of hypoxia.