NaCl对水稻谷氨酸合酶和谷氨酸脱氢酶的胁迫作用

在ＮａＣｌ的胁迫下,水稻幼苗根和叶的谷氨酸合酶和谷氨酸脱氢酶的活性随着营养液中的ＮａＣｌ浓度的升高而降低;游离ＮＨ４＾＋在叶中积累,在根中未见明显变化。与根相比,叶对ＮａＣｌ的胁迫作用更为敏感。叶的ＮＡＤＨ－ＧＯＧＡＴ和ＮＡＤＨ－ＧＤＨ活性在ＮａＣｌ胁迫降低的程度明显大于根。无论是否有ＮａＣｌ存在,根的ＮＡＤＨ－ＧＤＨ活性明显高于叶。ＧＳ／ＧＤＨ比值分析提示,对对照下,根中的ＮＨ４＾存在,根的ＮＡ     

REACTIONS OF FREE AND tRNA BOUND GLUTAMATE AND GLUTAMINE

—[¹⁴C]-Glutamate and [¹⁴C]-glutamine were incorporated into calf brain tRNA in the presence of homologous aminoacyl-tRNA synthetases. When the tRNAs were then deaminoacylated and chromatographed, a number of radioactive products were found in addition to the original amino acids. One of the products of glutamate transformation was identified to be glutamine. Formation of the radioactive products of glutamate in the presence and absence of tRNA indicated that glutamine was produced from glutamate at the level of the free amino acid followed by the incorporation of both substances into tRNA. Examination of the products of deaminoacylation of glutaminyl-tRNA showed that glutamine underwent structural alterations at the level of the aminoacyl-tRNAs to give rise to a cyclic derivative of glutarimide. This reaction was specific for glutamine, and constituted approximately 15 per cent of the total radioactivity in the deaminoacylation products of glutaminyl-tRNA.     

THE PURIFICATION AND PROPERTIES OF RAT BRAIN GLUTAMATE DEHYDROGENASE

—A method is described for the preparation of glutamate dehydrogenase in a highly purified form from rat brain. Only one protein band was detected when the enzyme was subjected to electrophoresis on SDS polyacrylamide gels. The rat brain enzyme was essentially identical to the rat liver enzyme with respect to electrophoresis on SDS polyacrylamide gels, immunochemical properties and most kinetic parameters. However, the brain enzyme was much less reactive with glutamate, was more sensitive to inhibition by haloperidol, and was considerably more stable than the liver enzyme.     

类产碱假单胞菌谷氨酸脱氢酶的纯化和性质

谷氨酸脱氢酶（Ｇｌｕｔａｍａｔｅｄｅｈｙｄｒｏｇｅｎａｓｅ,ＧＤＨ）可逆催化谷氨酸脱氨生成α酮戊二酸和氨,是一种依赖ＮＡＤ（Ｐ）的脱氢酶。其分子形式主要为六聚体或四聚体,大多数ＧＤＨ为六聚体［１］。该酶广泛存在于原核生物和真核生物,在氮、碳代谢的联系方面发挥重要作用。至今已有很多细菌ＧＤＨ得到详细研究［２～４］,但未见类产碱假单胞菌ＧＤＨ的研究报道。本文通过研究类产碱假单胞菌ＧＤＨ的纯化和性质,为揭示该菌的氮、碳代谢机制奠定基础。１　材料和方法１－１　细菌培养液体培养基为含柠檬酸和氯化铵的微量…     

BIOCHEMICAL CORRELATES OF TRANSMISSION MEDIATED BY GLUTAMATE AND ASPARTATE

Abstract— Glutamate and aspartate probably serve as transmitters of hippocampal perforant path and commissural afferents, respectively. We therefore used slices of hippocampal regions to evaluate certain biochemical properties as markers for sites of transmission mediated by these amino acids. In these studies content and accumulation of glutamate and aspartate were compared with their Ca²⁺-dependent effluxes.
Hippocampal regions varied little in their contents of glutamate and aspartate, but slices of regio superior and dentate gyrus accumulated and released more of each than slices of regio inferior. A commissurotomy or bilateral entorhinal lesion altered Ca²⁺-dependent efflux and accumulation in the same direction, but did not affect the glutamate or aspartate content of any hippocampal region. Elimination of hippocampal mossy fibers reduced the Ca²⁺-dependent efflux of glutamate and probably aspartate from slices of dentate gyrus, but not of regio inferior, where most mossy fiber synapses are located. The mossy fibers appeared relatively deficient in aspartate in both strains tested, but only in Purdue-Wistar rats were they enriched in glutamate. Removal of the perforant path input to the fascia dentata did not significantly change the activity of any of the enzymes most actively involved in glutamate synthesis.
These results suggest that accumulation or high affinity transport of glutamate or aspartate can be employed to localize afferents which use these amino acids as transmitters, although it is not so reliable or selective a marker as Ca²⁺-dependent efflux. Enrichment in either glutamate or aspartate content or in the activity of enzymes which synthesize them is not a reliable marker. Neither amino acid is likely to be used as a transmitter by the hippocampal mossy fibers.     

大鼠视皮质—外侧膝状体HRP示踪结合谷氨酸及GABA免疫组化研究

采用HRP逆行追踪观察了大鼠视皮质锥体细胞至外侧膝状体背核的投射,结合谷氨酸及GABA免疫组化方法探测了该类细胞的化学递质。光镜下HRP标记细胞与谷氨酸和GABA免疫阳性细胞清晰可辨。谷氨酸免疫阳性神经元主要分布在视皮质第Ⅱ～Ⅵ层。在第Ⅵ层可见HRP和谷氨酸双标记的锥体细胞,双标细胞的数量约占HRP标记细胞总数的42.7％。GABA免疫阳性神经元分布在皮质各层。但未见有GABA和HRP的双标记神经元。因而有充分理由推测:谷氨酸可能是视皮质投射至外侧膝状体背核的锥体细胞的神经递质之一。     

STUDIES ON THE REGULATION OF GABA SYNTHESIS: THE INTERACTION OF ADENINE NUCLEOTIDES AND GLUTAMATE WITH BRAIN GLUTAMATE DECARBOXYLASE

The effects of adenine nucleotides and glutamate on glutamate decarboxylase were studied in a dialyzed, high-speed supernatant of rat brain. When incubated with 10 μm -pyridoxal-P the enzyme was strongly inhibited by ATP, ADP and their Mg²⁺ complexes at concentrations which were well below tissue levels. The enzyme was not significantly inhibited by 15 mm -AMP or by 100 μM-3′-5’cyclic AMP or 3′-5’cyclic GMP. Inhibition by the nucleotides cannot be described in conventional steady-state kinetic terms. Addition of ATP in the presence of pyridoxal-P resulted in a slow, progressive decrease in the reaction rate which was similar to the inactivation observed when the enzyme was incubated in the absence of pyridoxal-P. The progressive inactivation in the presence of ATP was minimal at concentrations of glutamate which were well below K_m and became much more pronounced at higher glutamate concentrations. Addition of suprasaturating amounts of pyridoxal-P late in the incubation when the enzyme was almost completely inactivated resulted in an immediate and complete reactivation of the enzyme. Inhibition by ATP could be prevented by addition of saturating amounts of pyridoxal-P at the start of the reaction and was also relieved by addition of potassium phosphate buffer. The results suggest that inhibition by the nucleotides involves the prior formation of the inactive apoenzyme which results from the glutamate-promoted dissociation of pyridoxal-P. In the absence of the nucleotides, the enzyme is normally reactivated by the added pyridoxal-P. The nucleotides act to block this reassociation of pyridoxal-P with the apoenzyme thereby producing a progressive inactivation of the enzyme. The implications of these results for the regulation of GABA synthesis are discussed.     

KINETICS OF BRAIN GLUTAMATE DECARBOXYLASE. INTERACTIONS WITH GLUTAMATE,PYRIDOXAL 5-PHOSPHATE AND GLUTAMATE-PYRIDOXAL 5-PHOSPHATE SCHIFF BASE1

Abstract— The kinetic behavior of glutamate decarboxylase from mouse brain was analyzed in a wide range of glutamate and pyridoxal 5′-phosphate concentrations, approaching three limit conditions: (I) in the absence of glutamate-pyridoxal phosphate Schiff base; (II) when all glutamate is trapped in the form of Schiff base; (III) when all pyridoxal phosphate is trapped in the form of Schiff base. The experimental results in limit condition (I) are consistent with the existence of two different enzyme activities, one dependent and the other independent of free pyridoxal phosphate. The results obtained in limit conditions (II) and (III) give further support to this postulation. These data show that the free pyridoxal phosphate-dependent activity can be abolished when either all substrate or all cofactor are in the form of Schiff base. The free pyridoxal phosphate-independent activity is also abolished when all substrate is trapped as Schiff base, but it is not affected by the conversion of free pyridoxal phosphate into the Schiff base. A kinetic and mechanistic model for brain glutamate decarboxylase activity, which accounts for these observations as well as for the results of previous dead end-inhibition studies, is postulated. Computer simulations of this model, using the experimentally obtained kinetic constants, reproduced all the observed features of the enzyme behavior. The possible implications of the kinetic model for the regulation of the enzyme activity are discussed.     

友鼠外侧膝状体中继神经元HRP示踪结合谷氨酸免疫组织化学研究

采用 HRP逆行追踪结合谷氨酸免疫组织化学方法观察大鼠外侧膝状体背侧核 (d L GN)中继神经元的化学递质。光镜下 HRP标记细胞与谷氨酸免疫阳性细胞清晰可辩。HRP单标记细胞位于外侧膝状体背侧核内 ,胞浆及树突基部充满棕色颗粒。免疫金银法 (IGSS)单标记的谷氨酸免疫阳性神经元分布于外侧膝状体背侧核与腹侧核 ,胞体内充满黑色银颗粒。在外侧膝状体背侧核内可见 HRP和谷氨酸双标记细胞 ,其数目占 HRP标记细胞总数的 70 .9± 6 .4%。本文提示 ,谷氨酸可能是外侧膝状体背侧核投射至视皮质的中继神经元的神经递质之一。     

TOPOGRAPHICAL AND SUBCELLULAR DISTRIBUTION OF CHOLINE ACETYLTRANSFERASE AND GLUTAMATE DECARBOXYLASE IN PIGEON OPTIC TECTUM

Abstract— The distribution of choline acetyltransferase (ChAT) and glutamate decarboxylase (GAD) in different layers of the pigeon optic tectum and in some nuclei of the optic lobe have been investigated. About 40% of GAD and 25% of ChAT were found in the superficial part of tectum, but negligible activity was found in the stratum opticum. The highest GAD activity was found in layers 3-7 (according to the nomenclature of C ajal , 1911) with a peak in layer 4. ChAT activity peaked in layers 3, 5. 8 and 10/11. Its distribution correlated well with the staining pattern of AChE, particularly in the superficial part of the tectum. The distribution of ChAT and GAD did not change significantly 4 weeks after enucleation. ChAT and GAD activities were high in the nucleus isthmi, pars parvocellularis (Ipc). The activity of GAD was also high in the nucleus intercollicularis (ICo), the other nuclei showed less activity of both enzymes.     

EFFECTS OF GLUTAMATE AND OTHER AMINO ACIDS ON THE RETINA1

The application of unlabelled glutamate to the isolated chicken retina charged with [¹⁴C]glutamate caused an increase in the tissue transparency and a release of the label into the superfusion fluid. The processes causing the change in transparency were‘desensitized’by a prolonged application of unlabelled glutamate, whereas the release of the labelled amino acid was relatively unaffected. Mg²⁺ tended to depress the change in transparency caused by stimulation with unlabelled glutamate but had little effect on the release of labelled glutamate from the retina. The effect of a Ca²⁺-free superfusion fluid on the transparency and release of glutamate varied from retina to retina. Aspartate (in higher concentrations) elicited a change in transparency and release of the label in a manner similar to that of glutamate. Glutamine caused a change in transparency accompanied by a release of labelled glutamine and in some experiments the release of a small amount of labelled glutamate. Homocysteic acid elicited marked changes in transparency but no release of labelled glutamate. Pyroglutamate depressed both the change in transparency and the release of labelled glutamate caused by the unlabelled amino acid. Gamma-aminobutyric acid and glycine had no effect on the transparency of the tissue or on the release of amino acids. We have discussed the possibility that a release of glutamate from the intracellular compartment into the extracellular space is involved in the mechanism of spreading depression.     

THE GLUTAMATE AND GLUTAMINE CONTENT OF RAT BRAIN AFTER PORTOCAVAL ANASTOMOSIS

Abstract— Rats have been subjected to portocaval anastomosis and the ammonium ion in plasma and the glutamate and glutamine levels in plasma, red cells and brain have been estimated up to 6 weeks after operation. The glutamine, but not the glutamate, levels in brain were consistently raised, being about 2.5 times greater than normal and the level can be correlated with the level of plasma ammonium ion. Consideration is given to the possibility that the glutamine may be in the greatly enlarged neuroglial compartment in this abnormal metabolic state.     

METABOLISM OF GLUCOSE AND GLUTAMATE BY SYNAPTOSOMES FROM MAMMALIAN CEREBRAL CORTEX

—(1) Synaptosomes incubated in high sodium, low potassium media showed high linear respiration in the presence of glucose which was converted into lactate, aspartate, glutamate, glutamine, alanine and GABA during 1 hr incubation periods. (2) Total conversion of glucose into most of these substrates over the incubation period was similar in synaptosomes and cortex slices. Half the lactate and only a small fraction of the glutamine made by slices was formed by synaptosomes. (3) Pool sizes of amino acids in cortex slices after incubation with glucose were, in general, higher than in synaptosomes, glutamate and glutamine being four-fold higher in slices. (4) Most of the amino acids made from glucose by synaptosomes were contained within their structure and not lost to the medium. (5) Glutamate was actively metabolized by synaptosomes to aspartate, glutamine, alanine and GABA. The specific radioactivities of the amino acids (except glutamine) after 1 hr incubation, approached that of the glutamate. (6) Pyridoxal phosphate added to the incubation medium increased GABA production from glutamate but not from glucose.     

糖皮质激素对谷氨酸和DGABA受体的电生理反应的快速调制作用

在大鼠下丘脑薄片和豚鼠腹腔神经节上,分别用玻璃微电极细胞外和细胞内记录方法,观察了１０－６ｍｏｌ／Ｌ糖皮质激素（ＧＣ）对谷氨酸和ＧＡＢＡ受体介导效应的快速调制作用。结果表明,ＧＣ灌流后５ｍｉｎ,对谷氨酸受体介导的效应起抑制作用,而对ＧＡＢＡ受体介导的效应起增强作用。撤除ＧＣ后,神经元对谷氨酸和ＧＡＢＡ的反应恢复到对照水平。低钙高镁灌流液不能取消ＧＣ的调制作用。结果提示,ＧＣ在不需要突触环路条件下,可能通过非基因组途径影响谷氨酸和ＧＡＢＡ受体介导的效应。     

EFFECTS OF UNDER NUTRITION AND PROTEIN DEFICIENCY ON GLUTAMATE DEHYDROGENASE AND DECARBOXYLASE IN RAT BRAIN

Abstract— Studies were made on the effects of undernutrition at different ages during the neonatal period and of the comparative effects of postweaning protein and calorie deficiencies in neonatally undernourished or normally reared animals. Neonatal undernutrition resulted in deficits in body wt, brain wt and the activities of brain glutamate dehydrogenase and glutamate decarboxylase. Percentage deficits in brain wt were maximum in the first week of life but those in brain enzymes were greater in the second week. Rehabilitation of neonatally undernourished animals reversed the deficits in brain wt and brain enzymes. Post-weaning protein deficiency produced similar deficits in brain enzymes in both neonatally undernourished and normally reared animals. With post-weaning undernutrition, however, these deficits were found only in animals subjected to neonatal undernutrition as well.     

褪黑素对谷氨酸致痫大鼠海马内谷氨酸、GABA及其受体水平的影响

目的探讨褪黑素(melatonin,MT)对谷氨酸(glutamate,Glu)致痫大鼠海马内Glu及GluR2、γ-氨基丁酸(γ-aminobutyric-acid,GABA)及其受体GABRA1水平的影响,进而研究褪黑素的抑痫作用机制。方法随机将健康SD雄性大鼠40只分为A、B、C、D组,每组10只。A组:生理盐水组;B组:MT Glu组;C组:Glu致痫组;D组:Luzidole MT Glu组。观察并记录行为学变化,采用免疫组化法进行Glu、GluR2、GABA和GABRA1免疫组化染色和图像分析。结果行为学观察结果显示,C组和D组大鼠均有不同程度的癫痫发作,B组大鼠癫痫发作不明显,A组无发作;免疫组化结果显示,C组和D组海马内CA1-CA3区和齿状回Glu阳性反应较A组增强(P<0.05),GluR2、GABA和GABRA1均较A组减弱(P<0.05),B组Glu较C组和D组阳性反应有显著性减弱(P<0.05),GluR2、GABA和GABRA1阳性反应均较C组和D组有显著性增强(P<0.05),而B组与A组无明显差异性。结论MT通过增加GABA及其受体GABRA1和GluR2的作用和抑制Glu作用对Glu致痫大鼠癫痫发作发挥抑制作用。     

COUPLED TRANSPORT OF GLUTAMATE AND SODIUM IN A CEREBELLAR NERVE CELL LINE

The cerebellar nerve cell line ε¹ has a very effective active transport system for glutamate. Glutamate uptake is dependent on extracellular Na⁺ and furthermore, ²²Na⁺ uptake is stimulated by glutamate, indicating that glutamate uptake and Na⁺ uptake are coupled. Two molecules of Na ⁺ are transported for each molecule of glutamate. The K_m for glutamate is found to be 5 × 10^?5M in both the glutamate uptake assay and the ²²Na⁺ uptake assay, providing additional evidence for glutamate-Na⁺ coupling. Pre-incubation with ouabain, which inhibits the Na⁺-K⁺ ATPase, results in a gradual inhibition of glutamate uptake due to the deterioration of the Na⁺ gradient. Tetrodotoxin, however, has no effect on glutamate-induced ²²Na⁺ uptake, showing that this Na⁺ flux does not occur via voltage-dependent Na⁺ channels. Studies on the specificity of the ε¹ glutamate transport system show that it is distinct from systems that transport alanine and glycine. l -Glutamate, d -aspartate, l -cysteate, and l -cysteine sulfinate are able to utilize the transport system efficiently. d -Glutamate, l -homocysteate, N-methyl-d , l -aspartate, and kainic acid are very poor substrates for the glutamate transport system, and in addition do not stimulate ²²Na⁺ uptake. These data allow us to distinguish the glutamate transport system from the glutamate receptor which is known to mediate depolarization in response to all nine of the above compounds. Thus, ε¹ does not have an excitatory glutamate receptor.