Systematic analyses of glutamine and glutamate metabolisms across different cancer types

Background: Glutamine and glutamate are known to play important roles in cancer biology. However, no detailed information is available in terms of their levels of involvement in various biological processes across different cancer types, whereas such knowledge could be critical for understanding the distinct characteristics of different cancer types. Our computational study aimed to examine the functional roles of glutamine and glutamate across different cancer types.Methods: We conducted a comparative analysis of gene expression data of cancer tissues versus normal control tissues of 11 cancer types to understand glutamine and glutamate metabolisms in cancer. Specifically, we developed a linear regression model to assess differential contributions by glutamine and/or glutamate to each of seven biological processes in cancer versus control tissues.Results: While our computational predictions were consistent with some of the previous observations, multiple novel predictions were made:(1) glutamine is generally not involved in purine synthesis in cancer except for breast cancer, and is similarly not involved in pyridine synthesis except for kidney cancer;(2) glutamine is generally not involved in ATP production in cancer;(3) glutamine's contribution to nucleotide synthesis is minimal if any in cancer;(4) glutamine is not involved in asparagine synthesis in cancer except for bladder and lung cancers; and(5) glutamate does not contribute to serine synthesis except for bladder cancer.Conclusions: We comprehensively predicted the roles of glutamine and glutamate metabolisms in selected metabolic pathways in cancer tissues versus control tissues, which may lead to novel approaches to therapeutic development targeted at glutamine and/or glutamate metabolism. However, our predictions need further functional validation.

Glutamate reduces experimental intestinal hyperpermeability and facilitates glutamine support of gut integrity

AIM:To assess whether glutamate plays a similar role to glutamine in preserving gut wall integrity.METHODS:The effects of glutamine and glutamate on induced hyperpermeability in intestinal cell lines were studied.Paracellular hyperpermeability was induced in Caco2.BBE and HT-29CL.19A cell lines by adding phorbol-12,13-dibutyrate(PDB) apically,after which the effects of glutamine and glutamate on horseradish peroxidase(HRP) diffusion were studied.An inhibitor of glutamate transport(L-trans-pyrrolidine-2,4-dicarboxylic acid:trans-PDC) and an irreversible blocker(acivicin) of the extracellular glutamine to glutamate converting enzyme,γ-glutamyltransferase,were used.RESULTS:Apical to basolateral HRP flux increased significantly compared to controls not exposed to PDB (n=30,P<0.001).Glutamine application reduced hyperpermeability by 19%and 39%in the respective cell lines.Glutamate application reduced hyperpermeability by 30%and 20%,respectively.Incubation of HT29CL.19A cells with acivicin and subsequent PDB and glutamine addition increased permeability levels.Incubation of Caco2.BBE cells with trans-PDC followed by PDB and glutamate addition also resulted in high permeability levels.CONCLUSION:Apical glutamate-similar to glutaminecan decrease induced paracellular hyperpermeability.Extracellular conversion of glutamine to glutamate and subsequent uptake of glutamate could be a pivotal step in the mechanism underlying the protective effect of glutamine.

Glutamine and glutamate supplementation raise milk glutamine concentrations in lactating gilts

Glutamine is the most abundant amino acid in milk, and lactation is associated with increased glutamine utilization both for milk synthesis and as a fuel for the enlarged small intestine. A number of recent studies have indicated that lactation is accompanied by a mild catabolic state in which skeletal muscle proteins are degraded to provide amino acids that are used to synthesize additional glutamine. In this study we tested the hypothesis that supplemental L-glutamine or the commercially available glutamine supplement Aminogut （2.5% by weight mixed into daily feed） provided to gilts from 30 days prior to parturition until 21 days post-parturition would prevent a decrease in skeletal muscle glutamine while increasing the glutamine content of the milk. Muscle glutamine content decreased （P 〈 0.05） in control animals during lactation but this was prevented by supplementation with either L-glutamine or Aminogut. In this study, neither lactation nor supplementation had any effect on plasma glutamine or glutamate content. Free glutamine, and the total glutamine plus glutamate concentrations in milk from the control and the Aminogut group rose （P 〈 0.05） during the first 7 days of lactation, with milk concentrations in the L-glutamine supplemented group showing a similar trend （P = 0.053）. Milk glutamate remained constant between day 7 and 21 of lactation in the control and L-glutamine supplemented groups, but by day 21 of lactation the free glutamine, glutamate, and glutamine plus glutamate concentrations in milk from Aminogut-treated gilts were higher than those of control gilts. Thus dietary glutamine supplementation can alleviate the fall in intramuscular glutamine content during lactation in gilts, and may alleviate some of the catabolic effects of lactation. Furthermore, the increased milk glutamine content in the supplemented gilts may provide optimum nutrition for piglet development.

Effect of Exogenous Ammonium on GlutamineSynthetase, Glutamate Synthase, and Glutamate Dehydrogenase in the Root of Rice Seedling

Root biomass of rice seedlings was increased at lower concentration of exogenous NH 4 + , but it was decreased at higher concentration of exogenous NH 4 + . The level of free NH 4 + in the roots was accumulated gradually with the increase of NH 4 + concentration in the nutrient solution. The content of the soluble proteins was essentially constant at higher NH 4 + . The activities of glutamine synthetase (GS), NADH-dependent glutamate synthase (NADH-GOGAT), and NADH-dependent glutamate dehydrogenase (NADH-GDH) were risen with exogenous NH 4 + concentration at the lower NH 4 + concentration range. But the activities of GS and NADH-GOGAT were declined, and the level of NADH-GDH activity was kept constant under higher NH 4 + concentration. The GS/GDH ratio suggested that NH 4 + was assimilated by GS-GOGAT cycle under lower NH 4 + concentration, but NADH-GDH was more important for NH 4 + assimilation and detoxifying NH 4 + to the tissue cells at the higher NH 4 + level. According to the growth and the activity changes of these ammonium-assimilating enzymes of rice seedling roots, 10. 0 μg/mL NH 4 + -N in nutrient solution was more suitable to the rice growth.

Glutamine synthetase activity and glutamate uptake in hippocampus and frontal cortex in portal hypertensive rats

AIM: To study glutamine synthetase (GS) activity and glutamate uptake in the hippocampus and frontal cortex (FC) from rats with prehepatic portal vein hypertension. METHODS: Male Wistar rats were divided into shamoperated group and a portal hypertension (PH) group with a regulated stricture of the portal vein. Animals were sacrificed by decapitation 14 d after portal vein stricture. GS activity was determined in the hippocampus and FC. Specific uptake of radiolabeled L-glutamate was studied using synaptosome-enriched fractions that were freshly prepared from both brain areas. RESULTS: We observed that the activity of GS increased in the hippocampus of PH rats, as compared to control animals, and decreased in the FC. A significant decrease in glutamate uptake was found in both brain areas, and was more marked in the hippocampus. The decrease in glutamate uptake might have been caused by a deficient transport function, signif icantly and persistent increase in this excitatory neurotransmitter activity. CONCLUSION: The presence of moderate ammonia blood levels may add to the toxicity of excitotoxic glutamate in the brain, which causes alterations in brain function. Portal vein stricture that causes portal hypertension modif ies the normal function in some brain regions.

Formalin-induced astrocyte glutamate-glutamine cycle involved in rat spinal cord central sensitization

BACKGROUND： Central sensitization, a state of increased excitability of nociceptive neurons in the spinal dorsal horn following peripheral tissue injury and/or inflammation, is an important mechanism underlying hyperalgesia and neuropathic pain. Participation of the glutamate-glutamine cycle in central sensitization of the spinal cord remains poorly understood. OBJECTIVE： To determine whether the astrocyte-neuronal glutamate-glutamine cycle is involved in formalin-induced central sensitization in the spinal cord. DESIGN, TIME AND SETTING： A randomized, controlled, animal experiment was performed at the Institute of Orthopedics, Second Hospital, Lanzhou University, China from September 2007 to August 2008. MATERIALS： Methionine sulfoximine （MSO, 0.1 mmol/L）, glutamine （0.25 mmol/L）, and formalin were used for this study. METHODS： A total of 43 male, Sprague Dawley rats, aged 4 months, were randomly assigned to a sham operation group （n = 6） and a model group （n = 37）. Rats in the model group received intrathecal infusion in the spinal cord. 7 days later, 37 model rats were randomly divided into PBS, MSO, glutamine, MSO ＋ glutamine and formalin subcutaneous injection alone groups. The PBS, MSO, glutamine, MSO ＋ glutamine groups were respectively intrathecally injected with PBS, MSO, glutamine, MSO ＋ glutamine （50 μL each）, and then infused with 10 μL of saline. Rats from the sham operation group were not subjected to intrathecal infusion in the spinal cord. At 15 minutes after intrathecal injection, a rat model of formalin-induced inflammatory pain was established by subcutaneous injection of 5% formalin （50 μL） in the left hindpaw. MAIN OUTCOME MEASURES： Changes in spontaneous nociceptive behavior （licking/biting or flinching） were observed following formalin injection into the rat hindpaw. RESULTS： Compared with the PBS group, duration of licking/biting was significantly shortened, and flinching frequency was significantly diminished in the MSO group （P 〈 0.05）. Compared with the MSO group, duration of licking/biting was significantly prolonged, and flinching frequency was significantly increased in the MSO ＋ glutamine group （P 〈 0.05）. There was no significant difference in inflammatory pain behaviors among the sham operation, PBS, glutamine, MSO ＋ glutamine, and formalin subcutaneous injection alone groups （P 〉 0.05）. CONCLUSION： The astrocyte-neuronal glutamate-glutamine cycle in the spinal cord was shown to be involved in central sensitization induced by formalin subcutaneous injection into the hindpaw.

Astroglial glutamate-glutamine cycle is involved in the modulation of inflammatory nociception in rats

Our previous behavioral studies have indicated that the astroglial glutamate-giutamine cycle is involved in the process of formalin-induced spinal cord central sensitization, but there was little morphological evidence. In this study, double-labeling immunofluorescence techniques showed that after rats were intrathecally injected with PBS and plantarly injected with formalin, glial fibrillary acidic protein （GFAP） and glutamine synthesase （GS） expression were increased and GFAP/GS coexpression was changed to include layers III and IV. After intrathecal injection of methionine sulfoximine, a GS specific inhibitor, the formalin-induced change in expression and coexpression of GFAP and GS in spinal cord dorsal horns was inhibited. The morphology, distribution and quantity of astrocytes recovered to normal levels. An intrathecal glutamine injection reversed the inhibitory effect of methionine sulfoximine. Astrocytes showed significant activation and distribution extended to layers V and VI. The present study provides morphological evidence that the astroglial glutamateglutamine cycle is involved in the process of formalin-induced spinal cord central sensitization.

Alanine and aspartate aminotransferase and glutamine-cycling pathway:Their roles in pathogenesis of metabolic syndrome

Although new research technologies are constantly used to look either for genes or biomarkers in the prediction of metabolic syndrome(MS),the pathogenesis and pathophysiology of this complex disease remains a major challenge.Interestingly,Cheng et al recently investigated possible pathways underlying MS by high-throughput metabolite profiling in two large and well characterized community-based cohorts.The authors explored by liquid chromatography and mass spectrometry the plasma concentrations of 45 distinct metabolites and examined their relation to cardiometabolic risk,and observed that metabolic risk factors such as obesity,insulin resistance(IR),high blood pressure,and dyslipidemia were associated with several metabolites,including branched-chain amino acids,other hydrophobic amino acids,tryptophan breakdown products,and nucleotide metabolites.In addition,the authors found a significant association of IR traits with glutamine,glutamate and the glutamineto-glutamate ratio.These data provide new insight into the pathogenesis of MS-associated phenotypes and introduce a crucial role of glutamine-cycling pathway as prominently involved in the development of metabolic risk.We consider that the hypothesis about the role of abnormal glutamate metabolism in the pathogenesis of the MS is certainly challenging and suggests the critical role of the liver in the global metabolic modulation as glutamate metabolism is linked with aminotransferase reactions.We discuss here the critical role of the "liver metabolism" in the pathogenesis of the MS and IR,and postulate that before fatty liver develops,abnormal levels of liver enzymes,such as alanine and aspartate aminotransferases might reflect high levels of hepatic transamination of amino acids in the liver.

不同TSB水平新生儿期黄疸患儿T1WI信号强度、mI/Cr、Glx/Cr差异及对ABE的诊断价值

本研究旨在分析不同总胆红素(TSB)水平新生儿期黄疸患儿T1加权成像(T1WI)信号强度、mI/Cr、Glx/Cr差异,并探讨其对急性胆红素脑病(ABE)的诊断价值。选取118例新生儿期黄疸患儿,根据TSB水平分为3组(轻度组、中度组、重度组),均行颅脑磁共振成像(MRI)、磁共振波谱成像(MRS)检查。同时,根据是否并发ABE,分为单纯黄疸组和ABE组。比较各组患者总胆汁酸(TBA)、苍白球T1WI信号强度、MRS图像肌醇(mI)/肌酸复合物(Cr)、谷氨酸及谷氨酰胺复合物(Glx)/肌酸复合物(Cr)的变化情况。结果显示,不同组T1WI信号强度、MRS图像mI/Cr、Glx/Cr存在明显差异,且与TSB、TBA水平和新生儿期黄疸病情呈明显相关性。左侧、右侧苍白球T1WI信号强度,MRS图像mI/Cr、Glx/Cr诊断ABE的AUC分别为0.847、0.831、0.742、0.840。说明新生儿期黄疸患儿苍白球T1WI信号强度、MRS图像mI/Cr、Glx/Cr与血清TSB、TBA水平呈正相关,且各指标对ABE均有良好诊断价值,有利于ABE早期诊治。

Tb(lll) and Ca(ll) Ion Equilibria in the Presence of Glutamic Acid and Glutamine

Tb(111) and Ca(11) ion equilibria in the presence of glutamic acid and glutamine were studied by potentiometric titration at 37'C and an ionic strength of 0. 15mol/L(NaCl) .The stability constants for Tb(111) and Ca(11)complexes in the systems were obtained. The species and their distribution in the systems were discussed.

Methods for the Determination of Stable Isotopes of Carbon and Nitrogen Directly in Valine, Proline, Glutamine, and Glutamic Acid

Amino acids are very important compounds for the body and are involved in important functions that keep us healthy. Amino acids are essential components such as valine, proline, glutamine and glutamic acid. They can be synthesized either naturally or artificially. To examine the metabolism and regulate the synthesis process, compounds labeled with nitrogen or carbon isotopes need to be used. These isotopic compounds allow for more extensive research and enable studies that would otherwise be impossible. However, their use is dependent on the availability of simple, efficient methods for isotopic analysis. Currently, the determination of the atomic fraction of carbon and nitrogen isotopes is only possible through their conversion into molecular nitrogen or carbon monoxide or carbon dioxide. This leads to the loss of information about isotopic enrichment in specific centers of the molecule. This article explores a new direct approach to determining the atomic fraction of carbon and nitrogen isotopes in the isotope-modified or identical centers of these compounds. This method eliminates the transfer process and dilution due to nitrogen and carbon impurities. It is now possible to simultaneously determine the atomic fraction of nitrogen and carbon isotopes in the research substance. This method can be applied to amino acids, making it an effective tool for proposing new research methods. Several articles [1] [2] [3] have proposed similar methods for organic compounds and amino acids.

饲料中谷氨酸、谷氨酰胺和谷氨酸钠对鳜摄食、生长、胃肠及肝功能的影响

为研究谷氨酸(Glu)、谷氨酰胺(Gln)和谷氨酸钠(MSG)对鳜(Siniperca chuatsi)摄食、生长及胃肠功能的影响,以鳜基础饲料为对照组(CON),分别添加0.2%和0.4%的Glu、Gln和MSG,命名为Glu-0.2、Glu-0.4、Gln-0.2、Gln-0.4、MSG-0.2和MSG-0.4六个处理组,饲喂初始体质量为(17.60±0.53)g的鳜56d。同CON相比,结果显示:(1)三种添加剂均显著提高摄食量,其中MSG组最明显;(2)Glu-0.2和Gln-0.2的增重率、饲料转化率显著提高;(3)各添加组的胃蛋白酶活力和Glu-0.2、Glu-0.4、Gln-0.2的胃H+-K+-ATPase活力显著增强;(4)肠道中的胰蛋白酶活力在Glu-0.2显著提高,Na+-K+-ATPase活力在Gln-0.4无促进作用,其他组均显著增强;(5)Glu组、MSG组血浆中D-乳酸、内毒素含量和二胺氧化酶活性均显著降低;(6)Gln组血浆AST和ALT显著升高,且肝细胞肿胀、空泡化明显增多;(7)Glu组和MSG组血浆抗氧化能力显著升高,Gln组显著降低;(8)肠道微生物组成Glu-0.2的门水平软壁菌门(Tenericutes)、属水平索氏鲸杆菌属(Cetobacterium)丰度显著高于CON组。综上,Glu具有促进鳜胃酸分泌和胃肠消化吸收能力,增强肠道物理屏障,改善肠道菌群,促进生长;Gln能提升鳜胃肠功能,而机体抗氧化力、肝功能下降;MSG促进摄食和生长效果最佳,但对饲料转化无改善。

前庭性偏头痛患者丘脑谷氨酸-谷氨酰胺复合物代谢和相关因素分析

目的探索前庭性偏头痛(vestibular migraine,VM)患者双侧丘脑谷氨酸-谷氨酰胺复合物(glutamate/glutamine,Glx)代谢状态以及相关危险因素。材料与方法选取VM患者20例和健康对照者20例,用磁共振波谱(magnetic resonance spectroscopy,MRS)成像技术检测VM组和健康对照组的丘脑Glx含量。比较两组相关资料,分析Glx代谢差异及其危险因素。结果健康对照组(n=20)右侧丘脑Glx代谢值为2513.60±998.20,左侧丘脑Glx为2386.50±862.03。VM组(n=20)的右侧丘脑Glx代谢值为3712.00±980.80,左侧丘脑Glx为3350.40±944.20。t检验分析显示,与健康对照组相比,VM组左右侧丘脑Glx含量值差异均有统计学意义(P<0.05)。Spearman相关分析显示病程、糖尿病、高血压病、睡眠障碍程度和头痛程度,与VM丘脑Glx含量相关性无统计学意义;Pearson相关分析结果显示,眩晕障碍量表(Dizziness Handicap Inventory,DHI)、焦虑自评量表(Self-rating Anxiety Scale,SAS)和抑郁自评量表(Self-rating Depression Scale,SDS)评分与VM丘脑Glx含量相关性无统计学意义,年龄与左侧丘脑Glx含量相关性有统计学意义(r=0.570,P<0.001)。结论VM患者双侧丘脑Glx含量值高于健康对照者。年龄是左侧丘脑Glx含量升高的相关影响因素。

基于胱氨酸-谷氨酸反向转运体的抗肿瘤代谢治疗新策略

代谢重编程是恶性肿瘤的重要特征之一,是促使肿瘤细胞在营养匮乏的情况下存活并促进其恶性进展的重要原因。近些年研究发现,胱氨酸-谷氨酸反向转运体(system Xc^(-))不仅是诱导铁死亡的关键靶点,同时对肿瘤代谢起重要调控作用,该转运体是导致肿瘤细胞对葡萄糖高度依赖的原因之一,这提示对于高表达system Xc^(-)的肿瘤,抑制葡萄糖摄取及糖代谢是一种有效的治疗策略。本文从system Xc^(-)的表达调控、功能及其对肿瘤代谢的影响等方面进行综述,以期为抗肿瘤代谢治疗提供新思路。

脑内GABA代谢不足导致星形胶质细胞和少突胶质细胞功能广泛受损

神经代谢障碍性疾病琥珀酸半醛脱氢酶(SSADH)缺乏症会导致严重的神经化学失衡和严重的神经表现。该病的病因是SSADH酶功能丧失,导致主要抑制性神经递质γ-氨基丁酸(GABA)代谢受损。尽管已知酶缺乏的身份,但SSADH缺乏症的潜在病理机制仍不清楚。为了揭示该病的新机制,我们在SSADH缺乏症的遗传小鼠模型(ALDH5A1基因敲除小鼠)中进行了脑蛋白表达、功能代谢和脂质组成的非靶向整合分析。我们的蛋白质组学分析显示存在明显的区域脆弱性,因为蛋白质改变主要在ALDH5A1基因敲除小鼠的海马体和大脑皮质中表现出来。这些区域显示出与氨基酸稳态、线粒体、胶质细胞功能和髓鞘形成相关的蛋白质异常表达。在急性分离的脑切片中进行稳定同位素示踪显示,葡萄糖的氧化代谢总体上得以维持,但ALDH5A1基因敲除小鼠大脑皮质的星形胶质细胞代谢活性有所下降。相比之下,在ALDH5A1基因敲除小鼠的大脑中观察到氧化性谷氨酰胺代谢能力增强,这可能是星形胶质细胞谷氨酰胺供应受损的神经元补偿。除了少突胶质细胞关键蛋白表达减少外,ALDH5A1基因敲除小鼠大脑中还发现富含髓鞘的神经鞘脂严重耗竭,表明髓鞘退化。综上所述,我们的研究表明星形胶质细胞和少突胶质细胞功能障碍与SSADH缺乏症病理密切相关,提示选择性靶向胶质细胞可能在该病的治疗中具有潜力。

外源性谷氨酰胺和谷氨酸对早期断奶仔猪肠粘膜形态、结构和小肠吸收功能及骨骼肌中DNA、RNA浓度的影响

74头 2 8日龄健康二元杂交断奶仔猪分成 3组 ,用于研究外源性谷氨酰胺 (glutam ine,Gln)和谷氨酸 (glutamate,Glu)对断奶仔猪小肠粘膜形态、结构和功能及骨骼肌中 DNA、RNA合成的影响。结果表明 :与对照组相比 ,添加 1%谷氨酰胺或 1%谷氨酸可防止断奶后 1周内空肠绒毛萎缩 ,减少断奶后 2周内空肠固有膜内未成熟细胞数 ;显著改善断奶后 1周内小肠吸收功能 ,并促进肌肉中 RNA合成。这些结果为利用 Gln、Glu缓解仔猪断奶应激 ,改善生产性能提供了实验基础。

不同氮源对水稻幼苗根氨同化酶的影响

将氮素含量相同、但来源不同的氮源分别加入到水稻培养液中 ,分析了不同氮源对水稻幼苗根氨同化酶活性的影响 .与无氮培养的水稻根相比 ,( NH4) 2 SO4,NH4NO3,KNO3,谷氨酸 ( Glu)和谷氨酰胺 ( Gln)都能分别促进水稻根谷氨酰胺合成酶 ( GS)、依赖于 NADH的谷氨酸合酶 ( NADH- GOGAT)和依赖于 NADH的谷氨酸脱氢酶 ( NADH- GDH)活性 .( NH4) 2 SO4对 GS和 NADH- GOGAT活性促进最为显著 ,而 Gln对 GS和 Glu对 NADH-GOGAT的活性分别影响最小 .Glu对 NADH- GDH活性的诱导稍强于其它氮源 .这些结果提示 。

水稻氮素同化关键酶活性与叶色变化的关系

【目的】明确水稻叶色变化的内在生理机制。【方法】采用无氮肥和常规氮肥两个处理的水培试验,测定水稻地上部不同叶位叶片叶色值、叶绿素含量及氮素同化关键酶活性的变化。【结果】在氮饥饿和常规施肥条件下,水稻地上部不同叶位的叶色具有明显的黑黄变化规律。氮饥饿处理剑叶抽出前不同叶位叶片叶色值基本上表现为顶二叶>顶一叶>顶三叶,剑叶抽出后表现为顶一叶>顶二叶>顶三叶。不同叶位叶片GS、GOGAT活性分别在拔节期、剑叶抽出期出现两次高峰,各叶位的叶片GS、GOGAT活性基本表现为顶二叶>顶一叶>顶三叶。不同叶位叶片的GOGAT活性与当周叶片的SPAD值、叶绿素a、叶绿素b及叶绿素(a+b)含量均呈显著或极显著相关。常规施肥处理条件下水稻叶色及酶活性在整个生育期变化趋势与氮饥饿处理相似,GS酶活性与酶活性测定一周后的叶色关系非常密切,GOGAT活性与顶三、四叶叶色呈显著负相关,与酶活性测定1周后顶二、顶三叶的叶绿素a含量、2周后顶二、顶三叶的叶绿素(a+b)含量及2周后顶二叶的叶绿素b含量也呈显著正相关。【结论】水稻叶色变化是一个复杂的生理生化代谢过程,水稻不同叶位叶片叶色及氮素同化关键酶GS、GOGAT酶活性均具有明显的高低变化,氮素同化关键酶活性高低与叶绿素的合成及叶色变化具有密切的因果关系,在叶绿素的合成和叶色形成过程中具有一定作用。水稻叶色黑黄变化是一个受内生节奏制约的生物学过程,氮素水平对叶色深浅具有一定的调节作用,但不能改变内生黑黄变化节奏。

谷氨酸和谷氨酰胺对大鼠学习记忆的影响

为了观察谷氨酸(Glu)和谷氨酰胺(Gln)对大鼠学习记忆的影响并探讨其机理,选用Wistar大鼠36只,随机分为3组:对照组、Glu 组和Gln 组,分别给予普遍饲料、补充2% Glu 和2% Gln 的饲料喂养2周后,以穿梭箱实验作为学习记忆的行为模型对大鼠进行训练,记录主动回避反应次数和被动逃避时间,并用氨基酸自动分析仪、双波长比色法、放射性配基结合法分别测定了脑中游离氨基酸含量、一氧化氮合酶(NOS)活性和海马N-甲基-D-天冬氨酸受体(NMDA-R)的数目及亲和力。结果显示补充Gln 后,大鼠的主动回避反应率显著增加,被动逃避时间缩短,脑中Glu、天门冬氨酸Gln、精氨酸含量显著增高,NOS活性和海马NMDA-R数目亦增加,而补充Glu 组未观察到上述作用。结果提示:Gln 对大鼠的学习记忆具有促进作用,而Glu 则无此作用,推测其机理可能与脑中兴奋性氨基酸含量。