Increased excitatory amino acid transporter 2 levels in basolateral amygdala astrocytes mediate chronic stress–induced anxiety-like behavior

The conventional perception of astrocytes as mere supportive cells within the brain has recently been called into question by empirical evidence, which has revealed their active involvement in regulating brain function and encoding behaviors associated with emotions.Specifically, astrocytes in the basolateral amygdala have been found to play a role in the modulation of anxiety-like behaviors triggered by chronic stress. Nevertheless, the precise molecular mechanisms by which basolateral amygdala astrocytes regulate chronic stress–induced anxiety-like behaviors remain to be fully elucidated. In this study, we found that in a mouse model of anxiety triggered by unpredictable chronic mild stress, the expression of excitatory amino acid transporter 2 was upregulated in the basolateral amygdala. Interestingly, our findings indicate that the targeted knockdown of excitatory amino acid transporter 2 specifically within the basolateral amygdala astrocytes was able to rescue the anxiety-like behavior in mice subjected to stress. Furthermore, we found that the overexpression of excitatory amino acid transporter 2 in the basolateral amygdala, whether achieved through intracranial administration of excitatory amino acid transporter 2agonists or through injection of excitatory amino acid transporter 2-overexpressing viruses with GfaABC1D promoters, evoked anxiety-like behavior in mice. Our single-nucleus RNA sequencing analysis further confirmed that chronic stress induced an upregulation of excitatory amino acid transporter 2 specifically in astrocytes in the basolateral amygdala. Moreover, through in vivo calcium signal recordings, we found that the frequency of calcium activity in the basolateral amygdala of mice subjected to chronic stress was higher compared with normal mice.After knocking down the expression of excitatory amino acid transporter 2 in the basolateral amygdala, the frequency of calcium activity was not significantly increased, and anxiety-like behavior was obviously mitigated. Additionally, administration of an excitatory amino acid transporter 2 inhibitor in the basolateral amygdala yielded a notable reduction in anxiety level among mice subjected to stress. These results suggest that basolateral amygdala astrocytic excitatory amino acid transporter 2 plays a role in in the regulation of unpredictable chronic mild stress-induced anxiety-like behavior by impacting the activity of local glutamatergic neurons, and targeting excitatory amino acid transporter 2 in the basolateral amygdala holds therapeutic promise for addressing anxiety disorders.

The effect of excitatory amino acid transporters 2 on abnormal behavior of offspring influenced by prenatal stress

Aim Prenatal stress （PS） can lead to abnormal behavior of offspring and increase the incidence of mental illness. Previous researches have shown that levels of glutamate and its receptor expression are closely relat- ed to the occurrence of this phenomenon. Furthermore, recent study has demonstrated that the expression levels of excitatory amino acid transporters 2 （EAAT2） in different brain regions of 1 month PS offspring rats have changed. Methods The SD pregnant rats were used restraint stress to imitate PS from gestation 14 -~ 19 days. Offspring rats were weaned 21 days after birth. The expression of EAAT2 of hippocampus was observed by Western blot. Results The expression of EAAT2 of 1 month PS offspring rats was significantly decreased in comparison to control group. However, the expression of EAAT2 of 2 month PS offspring rats was significantly increased in comparison to 1 month PS offspring rats. Conclusion These phenomena have illustrated that the expression of EAAT2 of PS off- spring rats could show time dependence or reversibility. The expression of EAAT2 may play an important role in the development of mental illness of offspring rats influenced by PS.

Excitatory amino acid transporter supports inflammatory macrophageresponses

Excitatory amino acid transporters(EAATs) are responsible for excitatory amino acid transportation and are associated with auto-immune diseases in the central nervous system and peripheral tissues.However, the subcellular location and function of EAAT2 in macrophages are still obscure. In this study,we demonstrated that LPS stimulation increases expression of EAAT2(coded by Slc1a2) via NF-κB signaling. EAAT2 is necessary for inflammatory macrophage polarization through sustaining mTORC1 activation. Mechanistically, lysosomal EAAT2 mediates lysosomal glutamate and aspartate efflux to maintain V-ATPase activation, which sustains macropinocytosis and mTORC1. We also found that mice with myeloid depletion of Slc1a2 show alleviated inflammatory responses in LPS-induced systemic inflammation and high-fat diet induced obesity. Notably, patients with type Ⅱ diabetes(T2D) have a higher level of expression of lysosomal EAAT2 and activation of mTORC1 in blood macrophages. Taken together, our study links the subcellular location of amino acid transporters with the fate decision of immune cells,which provides potential therapeutic targets for the treatment of inflammatory diseases.

HBV相关肝细胞癌组织GLAST、GS蛋白表达及其与切除术后早期复发转移的关系

目的:检测乙型肝炎病毒(HBV)相关肝细胞癌组织兴奋性氨基酸转运体1(GLAST)、谷氨酰胺合成酶(GS)蛋白表达,并分析其与切除术后早期复发转移的关系。方法:选取本院2020年3月至2022年5月收治的125例实施切除术的HBV相关肝细胞癌患者,采用免疫组化法检测癌组织和切缘正常组织GLAST、GS蛋白表达。比较癌组织与切缘正常组织GLAST、GS蛋白阳性率;比较不同临床病理特征患者癌组织GLAST、GS蛋白阳性率;随访1年,Cox回归分析复发转移的影响因素。结果:癌组织GLAST、GS蛋白阳性率分别为28.57%、73.95%,前者低于切缘正常组织的57.98%,后者高于切缘正常组织的33.61%(P<0.05);HBV感染病程>22年患者癌组织GLAST蛋白阳性率均低于<10年、10~22年患者(P<0.05);肿瘤淋巴结转移(TNM)Ⅲ~Ⅳ期、有门静脉癌栓、未/低分化患者癌组织GLAST蛋白阳性率低于TNMⅠ~Ⅱ期、无门静脉癌栓、中/高分化患者(P<0.05),GS蛋白阳性率趋势相反;术后早期复发转移发生率为21.01%;年龄(HR=1.471,95%CI 1.086~1.993)、伴肝硬化(HR=1.728,95%CI 1.110~2.691)、GLAST蛋白阳性表达(HR=0.451,95%CI 0.224~0.910)、GS蛋白阳性表达(HR=2.255,95%CI 1.027~4.948)均是患者术后早期复发转移的影响因素(P<0.05)。结论:HBV相关肝细胞癌组织GLAST蛋白阳性率降低、GS蛋白阳性率升高,且二者均与切除术后早期复发转移有关。

兴奋性氨基酸转运体家族及其在眼科疾病中的研究进展

谷氨酸是哺乳动物中枢神经系统中的主要兴奋性神经递质,谷氨酸酶系统的持续激活会导致神经元的兴奋性毒性,进而引起神经元损伤和细胞死亡。兴奋性氨基酸转运体家族成员是一种多次跨膜蛋白,位于突触前膜、突触囊泡和神经胶质细胞膜上,也是一种高亲和力的钠钾依赖性载体,能够不断清除细胞外残留的谷氨酸,维持正常的突触内外谷氨酸水平和细胞内氧化还原稳态,对于保护细胞免受兴奋性毒性以及氧化应激损伤至关重要,兴奋性氨基酸转运体家族成员表水平达的失调与多种中枢神经系统疾病神经退行性变的发生和发展密切相关。在视网膜组织中,兴奋性氨基酸转运体家族成员广泛表达。目前大量研究表明,兴奋性氨基酸转运体家族成员广泛参与了青光眼、视网膜缺血再灌注损伤、年龄相关性黄斑变性等眼部疾病的发病,但具体机制有待进一步阐明。为此,文章综述了兴奋性氨基酸转运体家族成员的生理功能及其在相关眼科疾病发生和发展中作用的研究进展,为进一步阐明相关眼病发病的分子机制及新的防治靶点的发现提供新的视角。

Glutamate transporters, EAAT1 and EAAT2, are potentially important in the pathophysiology and treatment of schizophrenia and affective disorders

Glutamate is the predominant excitatory neurotransmitter in the human brain and it has been shown that prolonged activation of the glutamatergic system leads to nerve damage and cell death. Following release from the pre-synaptic neuron and synaptic transmission, glutamate is either taken up into the presynaptic neuron or neighbouring glia by transmembrane glutamate transporters. Excitatory amino acid transporter(EAAT) 1 and EAAT2 are Na+-dependant glutamate transporters expressed predominantly in glia cells of the central nervous system. As the most abundant glutamate transporters, their primary role is to modulate levels of glutamatergic excitability and prevent spill over of glutamate beyond the synapse. This role is facilitated through the binding and transportation of glutamate into astrocytes and microglia. The function of EAAT1 and EAAT2 is heavily regulated at the levels of gene expression, post-transcriptional splicing, glycosylation states and cell-surface trafficking of the protein. Both glutamatergic dysfunction and glial dysfunction have been proposed to be involved in psychiatric disorder. This review will present an overview of the roles that EAAT1 and EAAT2 play in modulating glutamatergic activity in the human brain, and mount an argument that these two transporters could be involved in the aetiologies of schizophrenia and affective disorders as well as represent potential drug targets for novel therapies for those disorders.

Expression of multiple glutamate transporter splice variants in the rodent testis

Glutamate is a regulated molecule in the mammalian testis. Extracellular regulation of glutamate in the body is determined largely by the expression of plasmalemmal glutamate transporters. We have examined by PCR, western blotting and immunocytochemistry the expression of a panel of sodium-dependent plasmalemmal glutamate transporters in the rat testis. Proteins examined included： glutamate aspartate transporter （GLAST）, glutamate transporter 1 （GLT1）, excitatory amino acid carrier 1 （EAAC1）, excitatory amino acid transporter 4 （EAAT4） and EAAT5. We demonstrate that many of the glutamate transporters in the testis are alternately spliced. GLAST is present as exon-3- and exon-9-skipping forms. GLT1 was similarly present as the alternately spliced forms GLT1 b and GLTlc, whereas the abundant brain form （GLTla） was detectable only at the mRNA level. EAAT5 was also strongly expressed, whereas EAAC1 and EAAT4 were absent. These patterns of expression were compared with the patterns of endogenous glutamate localization and with patterns of D-aspartate accumulation, as assessed by immunocytochemistry. The presence of multiple glutamate transporters in the testis, including unusually spliced forms, suggests that glutamate homeostasis may be critical in this organ. The apparent presence of many of these transporters in the testis and sperm may indicate a need for glutamate transport by such cells.

Role of astrocytic glutamate transporter in alcohol use disorder

Alcohol use disorder(AUD) is one of the most widespread neuropsychiatric conditions, having a significant health and socioeconomic impact. According to the 2014 World Health Organization global status report on alcohol and health, the harmful use of alcohol is responsible for 5.9% of all deaths worldwide. Additionally, 5.1% of the global burden of disease and injury is ascribed to alcohol(measured in disability adjusted life years, or disability adjusted life years). Although the neurobiological basis of AUD is highly complex, the corticostriatal circuit contributes significantly to the development of addictive behaviors. In-depth investigation into the changes of the neurotransmitters in this circuit, dopamine, gamma-aminobutyricacid, and glutamate, and their corresponding neuronal receptors in AUD and other addictions enable us to understand the molecular basis of AUD. However, these discoveries have also revealed a dearth of knowledge regarding contributions from nonneuronal sources. Astrocytes, though intimately involved in synaptic function, had until recently been noticeably overlooked in their potential role in AUD. One major function of the astrocyte is protecting neurons from excitotoxicity by removing glutamate from the synapse via excitatory amino acid transporter type 2. The importance of this key transporter in addiction, as well as ethanol withdrawal, has recently become evident, though its regulation is still under investigation. Historically, pharmacotherapy for AUD has been focused on altering the activity of neuronal glutamate receptors. However, recent clinical evidence has supported the animal-based findings, showing that regulating glutamate homeostasis contributes to successful management of recovery from AUD.

Dynamic expression of cerebral cortex and hippocampal glutamate transporters in a rat model of chest compression-induced global cerebral ischemia

The present study established a rat model of global cerebral ischemia induced by chest compression for six minutes to dynamically observe expressional changes of three glutamate transporters in the cerebral cortex and hippocampus. After 24 hours of ischemia, expression of glutamate transporter-1 significantly decreased in the cerebral cortex and hippocampus, which was accompanied by neuronal necrosis. At 7 days post-ischemia, expression of excitatory amino acid carrier 1 decreased in the hippocampal CA1 region and cortex, and was accompanied by apoptosis Expression of glutamate-aspartate transporter remained unchanged at 6 hours 7 days after ischemia. These results suggested that glutamate transporter levels were altered at different periods of cerebral ischemia.

兴奋性氨基酸受体的激活介导冷水应激诱导的tau蛋白磷酸化(英文)

为探讨兴奋性神经传递系统是否参与冷水应激引起的tau蛋白磷酸化,将小鼠于4℃冷水应激5min.采用免疫印迹和免疫组织化学方法分析应激后脑内c-fos和磷酸化tau蛋白的表达情况;运用HPLC检测冷水应激后小鼠脑内兴奋性或抑制性神经递质的变化;同时分析兴奋性氨基酸受体和L-型钙通道拮抗剂预处理后冷水应激小鼠脑内磷酸化tau蛋白的水平.冷水应激后1h,海马内磷酸化tau蛋白的水平显著升高,同时伴c-fos的染色增加.HPLC检测显示,兴奋性和抑制性神经递质呈现急剧上升而后又下降的趋势.冷水应激后15min,天冬氨酸和甘氨酸水平显著升高,1h后天冬氨酸、谷氨酸、牛磺酸和γ-氨基丁酸显著下降.NMDA受体拮抗剂MK-801(5mg/kg)和AMPA受体拮抗剂DNQX(0.5,5mg/kg)可显著抑制冷水应激引起的磷酸化tau蛋白水平的升高,代谢性谷氨酸受体拮抗剂MAP-4不影响tau蛋白的磷酸化,另外,L-型钙通道阻断剂尼莫地平可抑制冷水应激引起的磷酸化tau蛋白水平的升高.这些结果表明,冷水应激可影响兴奋性神经传递系统,通过离子型兴奋性氨基酸受体和异常神经激活来调节tau蛋白的磷酸化.兴奋性神经传递系统的激活在冷水应激诱导的海马tau蛋白的磷酸化中发挥作用.

岗田酸诱导大鼠脑神经细胞表达谷氨酸转运体EAAT1

为研究tau蛋白高度磷酸化与谷氨酸转运体功能之间的关系,实验采用免疫组织化学、荧光双标记技术及大鼠额叶皮质定位注射的方法,观察了蛋白磷酸酶抑制剂岗田酸（okadaic acid,OA）所致神经细胞退化对谷氨酸转运体亚型EAAT1表达的影响。结果如下:（1）在OA注射中心区神经元早期出现胞体固缩、肿胀、核移位,在注射3d时细胞破碎,发生坏死,并有大量炎性细胞浸润等病理现象;边周区细胞呈AT8（微管相关蛋白tau磷酸化指标）免疫阳性反应;（2）OA首先诱导神经细胞突起远端tau蛋白磷酸化,并逐渐向胞体发展,形成营养不良的神经细胞突起和神经纤维缠结样病理改变;（3）AT8免疫阳性反应脑区的神经细胞高表达谷氨酸转运体EAAT1,在12h阳性表达细胞数显著增多（P<0.01）,1d时达峰值（P<0.001）,3d时明显减少。在OA作用下EAAT1表达于星形胶质细胞和神经元。结果提示,OA致微管相关蛋白tau高度磷酸化时可诱导该区星形胶质细胞和神经元高表达谷氨酸转运体EAAT1。EAAT1高表达的病理生理意义有待进一步的阐明。

人参调节海马星形胶质细胞兴奋性氨基酸转运功能拮抗小鼠应激障碍的研究

目的观察应激对小鼠海马星形胶质细胞兴奋性氨基酸转运功能的影响,并探讨人参水煎液对此功能紊乱的调节作用。方法100只雄性ICR小鼠随机分为10组,对照组和模型组各5组。应激模型采用腹腔注射皮质酮,10组动物分配至5个时间点(1、2、3、4、5周)进行实验。另取30只雄性ICR小鼠分为对照组、模型组和人参干预组,每组10只。2组实验独立开展,实验周期均为5周。实验结束后,检测体质量、行为学、神经元结构/功能指标(NF-L、SYP)、星形胶质细胞生物标志指标(GFAP)和兴奋性氨基酸转运功能指标(EAATs),进行统计学分析。结果皮质酮注射1~3周小鼠海马星形胶质细胞标志蛋白反应性高表达,第3周末表达水平下调(P<0.05),同时神经元结构功能指标表达下调提示神经元损伤,实验动物出现体质量和行为学的显著改变(P<0.05)。进一步检测星形胶质细胞兴奋性氨基酸转运蛋白,显示表达下调,并与神经元损伤呈正相关性。人参干预组对模型小鼠EAATs、GFAP、NF-L和SYP的表达下降均有显著改善作用(P<0.05)。结论腹腔注射皮质酮可使小鼠海马神经元损伤并出现行为学异常,其机制可能是应激影响星形胶质细胞兴奋性氨基酸转运功能所导致,人参水煎液可通过此机制发挥抗应激作用。

地塞米松对缺氧缺血新生大鼠脑组织兴奋性氨基酸和单胺类神经递质的影响

目的观察地塞米松(DEX)对缺氧缺血新生大鼠脑组织兴奋性氨基酸(EAA)和单胺类神经递质含量的影响,探讨其在HIE致脑损伤中的作用。方法建立HIE动物模型,应用高效毛细管电泳和荧光分光光度法,分别检测假手术组、HIE组、小剂量DEX干预组(0.5 mg/kg)及大剂量DEX干预组(10 mg/kg)脑组织EAA及单胺类神经递质含量。结果HIE组EAA及单胺类神经递质含量均较假手术组明显升高(P均<0.01);小剂量DEX组EAA及单胺类神经递质含量与HIE组无明显变化(P>0.05);大剂量DEX组EAA含量较HIE组明显减少(P<0.01),较小剂量DEX组减少(P<0.05);大剂量DEX组单胺类神经递质含量较HIE组及小剂量DEX组均明显降低(P均<0.01)。结论缺氧缺血促进脑组织EAA及单胺类神经递质的释放;大剂量DEX干预可能通过抑制EAA及单胺类神经递质的释放,对HIE脑损伤起保护作用。

铝螯合剂对铝染毒大鼠学习记忆及兴奋性氨基酸类神经递质的影响

目的探讨铝螯合剂1,2-二甲基-3-羟基-4-吡啶酮(DFP)对铝染毒大鼠学习和记忆能力以及脑组织中天门冬氨酸(Asp)、谷氨酸(G1u)两种兴奋性氨基酸类神经递质含量的影响。方法将SPF级健康雄性Wistar大鼠35只按体重随机分为5个组,分别为阴性对照组(给予1 ml/d生理盐水,连续10周),铝染毒组[前8周给予AlCl_3 354.7 mg/(kg·d),后2周给予生理盐水1 ml/d],铝+DFP低、中、高剂量组[前8周给予AlCl_3 354.7 mg/(kg·d),后2周分别给予DFP 13.82、27.44、54.88 mg/(kg·d)],每组7只,均以灌胃方式染毒。采用Y型迷宫实验观察大鼠学习记忆能力的改变,采用高效液相色谱法测定各组大鼠脑组织中Asp、Glu的含量。结果各组大鼠体重间比较,差异无统计学意义(P>0.05)。Y型迷宫实验结果显示,铝+DFP高剂量组潜伏期短于铝染毒组,差异均有统计学意义(P<0.05);且各铝+DFP剂量组潜伏期与阴性对照组比较,差异均无统计学意义(P>0.05)。铝染毒组大鼠错误次数多于阴性对照组,各铝+DFP剂量组错误次数均少于铝染毒组,差异均有统计学意义(P<0.05);各铝+DFP剂量组错误次数与阴性对照组比较,差异均无统计学意义(p>0.05)。铝+DFP低、中、高剂量组天门冬氨酸和谷氨酸含量均高于铝染毒组,低于阴性对照组,差异均有统计学意义(P<0.01)。结论DFP能够升高染铝大鼠脑组织中兴奋性氨基酸类神经递质含量,有效地改善染铝大鼠学习记忆能力,对中枢神经系统有明显的保护作用。

高亲和力谷氨酸转运体

高亲和力谷氨酸转运体主要位于神经元和胶质细胞的细胞膜上 ,能逆浓度梯度从胞外向胞内摄取谷氨酸 ,中止谷氨酸能传递 ,使胞外谷氨酸浓度保持在较低水平 ,以保护神经元不受谷氨酸的毒性影响。近年来 ,随着高亲和力谷氨酸转运体的克隆 ,有关研究迅速发展。本文从高亲和力谷氨酸转运体的克隆、分子结构特征、表达分布、生理功能、结构

吗啡诱导的CPP复燃大鼠前额叶皮层和海马区EAAT3蛋白表达的变化

目的:观察吗啡诱导的条件性位置偏爱(CPP)复燃大鼠前额叶皮层和海马区兴奋性氨基酸转运蛋白3(EAAT3)的表达变化,探讨前脑皮层及海马区EAAT3在阿片类药物复吸过程中的作用。方法:成年雄性SD大鼠40只,随机分为对照组(control)、CPP建立(Es)、消退(Ex)、复燃2 h(Re2)、复燃4 h(Re4)组,每组8只。腹腔注射吗啡(10 mg/kg)连续10 d,建立CPP模型;停止给药使CPP逐渐消退;单次腹腔注射吗啡2.5 mg/kg诱导已消退的CPP复燃。Western blotting检测各组大鼠前额叶皮层和海马区EAAT3蛋白表达变化。结果:(1)腹腔注射恒定剂量的吗啡10 mg/kg,Es组大鼠在伴药箱的停留时间比control组明显延长(P<0.05),成功建立CPP模型;待CPP消退后,吗啡2.5 mg/kg腹腔注射诱发Re2和Re4组大鼠在伴药箱的停留时间再次比control组明显延长(P<0.05),CPP复燃。(2)Es组前额叶皮层EAAT3比control组表达减少(P<0.05),CPP消退的Ex组表达回升,在Re4组表达再次减少(P<0.05)。(3)海马区EAAT3在各组表达水平未见明显变化(P>0.05);而Es、Ex组海马CA1区EAAT3比control组表达明显升高(P<0.05)。结论:吗啡诱导CPP复燃时,前额叶皮层EAAT3的蛋白表达水平降低,重现CPP建立时的变化,提示阿片类药物复吸行为的形成可能与前脑皮层EAAT3的表达减少有关。

兴奋性氨基酸转运体研究进展

兴奋性氨基酸转运体 (EAAT)位于突触前膜、突触囊泡和神经胶质细胞膜上。它们对于兴奋性氨基酸的再循环 ,兴奋性信号的终止以及保护神经细胞免受兴奋性毒性损害具有特别重要的意义。

蝙蝠葛酚性碱对局灶性脑缺血大鼠海马神经细胞谷氨酸转运体EAAC1 mRNA表达的影响

目的探讨蝙蝠葛酚性碱(PAMd)对大鼠局灶性脑缺血后海马神经细胞谷氨酸转运体EAAC1 mRNA表达的影响,及其对脑缺血的保护机制。方法 SD大鼠42只,随机分为假手术组(不给药)、模型对照组(不给药)、PAMd组(灌胃给予PAMd 10 mg·kg-1),每组14只。线栓法制备大鼠局灶性脑缺血模型。采用2,3,5-氯化三苯基四氮唑(TTC)染色检测脑梗死体积,逆转录-聚合酶链反应(RT-PCR)检测海马神经细胞谷氨酸转运体EAAC1 mRNA表达。结果缺血24 h后,假手术组、模型对照组和PAMd组脑梗死比例分别为(0.0±0.0)%,(35.3±2.9)%,(21.3±3.8)%(P<0.05);缺血侧海马EAAC1 mRNA相对表达量分别为0.97±0.04,2.46±0.13,1.91±0.15(P<0.05)。结论 PAMd可能通过下调缺血后EAAC1的表达升高,从而减轻谷氨酸的兴奋毒性作用,发挥对脑缺血的保护作用。

谷氨酸转运体3在神经功能调节中的作用研究进展

谷氨酸是哺乳动物中枢神经系统内一种主要的兴奋性神经递质,当神经元突触间隙出现大量兴奋性氨基酸堆积时,就可造成神经毒性作用甚至细胞死亡,进而出现认知功能改变及其他的精神神经疾病。引起兴奋性氨基酸堆积的原因很多,其中兴奋性氨基酸转运体(EAAT)的改变与其密切相关,而EAAT3是谷氨酸转运体之一,它对突触间谷氨酸浓度的调控、谷胱甘肽(中枢神经系统的抗氧化剂)的合成具有重要意义。另外,EAAT3本身与神经保护以及认知功能也密切相关。

阿利吉仑对氧糖剥夺损伤的SH-SY5Y细胞的保护作用及可能机制

目的:探讨阿利吉仑对氧糖剥夺(OGD)损伤的神经母细胞瘤SH-SY5Y细胞的保护作用及可能机制。方法:将SH-SY5Y细胞随机分为对照组、OGD组及阿利吉仑低、中和高剂量(5.0、10.0和20.0 μmol/L)组。CCK-8法检测细胞活力;ELISA检测兴奋性氨基酸转运蛋白2(EAAT2/GLT-1)、兴奋性氨基酸转运蛋白3(EAAT3/EAAC1)、兴奋性氨基酸转运蛋白4(EAAT4)、内皮素1(ET-1)和S100钙结合蛋白β亚基(S-100β)的表达;Hoechst 33258染色观察SH-SY5Y细胞形态变化;乳酸(LD)测试盒和超微量Na +-K +-ATP酶测试盒检测LD含量和Na +-K +-ATPase活性。结果: OGD损伤4 h时,细胞相对活力不足60%,因此4 h可作为后续实验OGD造模时间。与对照组相比,OGD组的GLT-1、EAAC1和EAAT4表达显著下调( P <0.05),ET-1和S-100β的表达显著上调( P <0.05);与OGD组相比,阿利吉仑组的GLT-1、EAAC1和EAAT4表达呈剂量依赖性上调, ET-1和S-100β表达呈剂量依赖性下调( P <0.05)。Hochest 33258染色结果表明,阿利吉仑可明显减少OGD引起的SH-SY5Y细胞凋亡。与对照组相比,OGD组的LD含量显著升高( P <0.05),Na +-K +-ATPase活性显著降低( P <0.05);与OGD组相比,阿利吉仑组的LD含量呈剂量依赖性降低,Na +-K +-ATPase活性呈剂量依赖性升高( P <0.05)。结论:阿利吉仑对OGD损伤的SH-SY5Y细胞有一定的保护作用,其机制可能与阿利吉仑上调GLT-1、EAAC1和EAAT4的水平,提高Na +-K +-ATPase的活性,下调ET-1和S-100β的表达及LD含量有关。