缺氧小鼠脑中神经节苷脂和单胺类神经递质水平

脑缺氧和缺氧后的再灌注常导致一系列复杂的生理生化改变．通过小鼠重复缺氧后,观察其脑组织中的神经节苷脂和单胺类递质水平变化情况,发现重复缺氧时,随着缺氧次数的增加,a．神经节苷脂水平（以唾液酸含量表示）非常明显地持续下降(P<0.01),其中GM1与GD1b相对组分百分比值下降尤为突出(GM1:P<0.05,GD1b:P<0.01); b.单胺类神经递质中NE和DOPA水平下降,DA和HIAA水平升高(P<0.01)．结果提示脑组织经重复缺氧后,中枢神经组织细胞膜受到一定程度的损伤,其结果可能影响到单胺类神经递质的合成、释放、重摄取和贮存的全过程;据此推测脑组织缺氧时神经节苷脂与单胺类神经递质水平改变时存在着相互联系．     

猪脑神经节苷脂的测定及其分析

神经节苷脂是神经酰胺寡糖苷类物质.在脊椎动物的中抠神经系统中含量十分丰富.猪脑神经节苷脂经分离、纯化后的成分和含量的分析显示,猪脑神经节苷脂的含量占猪脑组织重量的0.0894%(W/W),是猪脑总脂含量的0.39%(W/W).主要成分是GM1,GD3,GD1a,GD1b和GT1b,其中GM1和GD1a明显高于人脑.     

猪脑中提取高纯度神经节苷脂

应用凝胶层析和离心液相层析法,从猪脑中提取高纯度神经节苷脂(Gls).按脂结合唾液酸(LBSA)计为30.1%,经硅胶薄层层析,580nm扫描结果表明含5种Gls,即:GM1为19.5%,GD3为13.8%,GD1a为27.8%,GD1b为14.2%和GT1b为19.3%.     

高效薄层层析-病毒覆盖结合法比较细胞表面神经节苷脂与不同动物源性新城疫病毒结合特性

【目的】神经节苷脂是新城疫病毒入侵宿主细胞的受体,但不同动物源性的新城疫病毒利用受体的特性是否存在差异尚不明确。以鹅源新城疫病毒NA-1株和鸡源新城疫病毒F48E9株为研究对象,比较两株病毒受体结合特性的差异。【方法】提取鸡胚和鹅胚成纤维细胞新城疫病毒受体成分——神经节苷脂,用高效薄层层析法比较两种细胞所含神经节苷脂的类型和含量;通过高效薄层层析-病毒覆盖结合法比较两种病毒与不同细胞神经节苷脂的结合特性,最后通过病毒红细胞吸附抑制试验进一步验证神经节苷脂与病毒之间的相互作用关系。【结果】鸡胚和鹅胚成纤维细胞所含的神经节苷脂成分存在明显差异;高效薄层层析-病毒覆盖结合实验结果显示NA-1和F48E9与神经节苷脂的结合模式不同,NA-1主要与神经节苷脂GD1a结合,即包含双SAα2,3Gal末端的神经节苷脂,而F48E9可与更多类型的神经节苷脂结合,从单唾液酸到三唾液酸形式的神经节苷脂如GM1、GD1a、GD1b、GT1b等。【结论】鹅源新城疫病毒NA-1株和鸡源新城疫病毒F48E9株在入侵靶细胞时优先选择利用的受体不同。     

产唾液酸酶微生物的筛选及产酶条件的优化

以无单唾液酸四己糖神经节苷脂（GM1）的神经节苷脂为唯一C源,从土壤中筛选出1株能以多唾液酸神经节苷脂为底物,转化生成GM1的产唾液酸酶微生物,经鉴定为溶黄嘌呤厄菌（Oerskovia xanthineolytica）。利用单因素法和响应面分析法对溶黄嘌呤厄菌产生唾液酸酶的条件进行优化,酶活提高了4.89倍。利用优化后培养条件,以神经节苷脂混合体为底物,经过微生物生物转化后,单唾液酸神经节苷脂GM1的含量从10%提高到83.7%。     

人黑色素瘤神经节苷脂对介素2(1L-2)T细胞免疫应答

<正> 常见的人黑色素瘤细胞上主要有四种神经节苷脂(GM3、GD3、GM2和GD2),它们对黑色素瘤病人的淋巴细胞起免疫调节作用。特异性黑色素瘤神经节苷脂对IL-2具有选择性的相互作用。 GM2和GD 2增强淋巴细胞对IL-2的应答,而GM 3和GD 3则相反。该差别来自GM 2和GD 2末端N-乙酸氨基半乳糖的存在。不同的神经节苷脂能以不同的方向调节淋巴细胞对IL-2的应答。 黑色素瘤细胞失去膜表面所含的神经节苷脂,则影响肿瘤附近或较远的淋巴细胞的功能。 经标准神经节苷脂TLC板分析,证明在高密度出现GM 3和GD 3,在低密度出现G-M2和GD 2。初期黑色素瘤的局部淋巴结或血液的淋巴细胞,通过标准聚蔗糖-泛影梯     

自发性可移植性615小鼠肺癌和肝癌组织神经节苷脂高效薄层层析图谱的分析

本文研究了615近交系小鼠的自发性可移植性肺癌(P_(615))和肝癌(H_(615))组织中神经节苷脂结合唾液酸含量和神经节苷脂图谱。P_(615)和H_(615)癌组织中GLS结合唾液酸含量均比正常对照为高,分别为对照组织的2.9倍和1.9倍。615小鼠的正常肺组织和肝组织的GLS主要成分均为GM_3。在P_(615)和H_(615)癌组织中GM_3含量均明显减少。肺癌组织中GM_2大量增加,肝癌组织中不仅GM_2明显增加,GM_1和GD_(18)也明显增加。P_(615)和H_(615)这两种分化程度较高、恶性程度较低的癌组织GD_3的百分含量比正常对照组织略有降低。本文结果提示,自发性可移植性P_(615)和H_(615)肿瘤组织中不仅神经节苷脂含量(以唾液酸量计)升高,而且GLS的组分也发生改变。GM_3含量减少和GM_2含量增高可能与肿瘤的恶性生长和分化程度有关。     

神经节苷脂与头部贴敷式亚低温联合治疗对新生鼠缺氧缺血性脑损伤的影响

目的:研究神经节苷脂与头部贴敷式亚低温联合治疗新生鼠缺氧缺血性脑损伤时脑组织内一氧化氮(NO)和(MDA)含量的变化,为新生儿缺氧缺血性脑病的治疗提供理论依据.方法:将88只WISTAR新生鼠随机分为四组,神经节苷脂治疗组(IG)、头部贴敷式亚低温治疗组(IH)、联合治疗组(IB)以及对照组(CN).结果:CN组NO和MDA的含量明显升高,IG、IH以及IB组NO和MDA均明显下降.结论:神经节苷脂和亚低温通过降低NO和MDA的含量保护缺氧缺血神经元,二者联合效果更好.     

神经节苷脂GM1对帕金森模型小鼠黑质细胞凋亡及Bcl-2和Bax表达的影响

目的观察神经节苷脂GM1对帕金森模型小鼠黑质细胞凋亡及Bcl-2和Bax表达的影响,探讨其预防帕金森病的机制。方法成年C57-BL雄性小鼠分为正常对照组、模型组和神经节苷脂GMI治疗组。应用TUNEL法和免疫荧光组织化学染色技术观察各组小鼠黑质神经元凋亡及Bcl-2和Bax表达情况。结果TUNEL、Bcl-2和Bax阳性神经元主要位于黑质致密部。模型组黑质神经元凋亡数明显多于正常对照组,神经节苷脂GM1组黑质神经元凋亡数明显少于模型组。在模型组Bcl-2阳性神经元和Bax阳性神经元的数量均较正常对照组明显增多;在神经节苷脂GM1组Bcl-2阳性神经元的数量较模型组明显增多,但Bax阳性神经元的数量较模型组明显减少。结论神经节苷脂GM1可能通过增强黑质神经元内Bcl-2基因表达及抑制Bax基因表达的途径抑制黑质神经元的凋亡。     

人正常子宫肌肉的鞘糖脂组成及其在不同生理功能阶段的变化

本文测定了新生儿、生育期、更年期和足月妊娠人子宫肌肉的神经节苷脂(Gg)与中性鞘糖脂(N-GSL)的含量,比较了两种鞘糖脂的HPTLC谱。新生儿期Gg的总含量(以脂结合唾液酸LBSA量表示)最高,每克湿重组织约45.2μg,足月妊娠子宫肌肉中的含量最低,为10.4μg,生育期为32.8μg、更年期为39.5μg。N—GSL的含量却以足月妊娠子宫肌肉中最多,达99.4μg。按HPTLC谱分析子宫肌肉中Gg的主要组分为GD_3和GM_3,在子宫发育成熟与妊娠时,肌肉组织中这两种组分的含量变化明显:生育期样品的GD_3由新生儿的25.4％增加到56.6％(按占LBSA总量的百分比计算),GM_3则由33.2％降至16.9％。此外,GM_1和GD_(1a)也明显减少。N—GSL在生育期CMH、CDH和CTH的含量(按占含糖基量的百分比计算)成倍增加,而含五糖基以上的组分则仅为新生儿子宫的1/5。足月妊娠与新生儿子宫肌肉的两类鞘糖脂的HPTLC谱类似,但前者GT1b占19.4％,明显高于新生儿样品(6.1％)。     

急性重复缺氧对小鼠脑组织腺苷及其A1受体的影响

分别应用酶鉴别分光光度法和放射性配体结合法测定小鼠脑组织腺苷（ａｄｅｎｏｓｉｎｅ,ＡＤＯ）含量及Ａ１受体在急性重复缺氧过程中的变化。发现经急性重复缺氧处理的动物全脑内ＡＤＯ含量有一定程度的累积增加,尤其在海马、脑桥和延髓处的增加较为显著;各脑区Ａ１受体的数目显著低于正常对照组,但海马、脑桥和延髓处Ａ１受体的亲和力显著高于正常对照组。结果提示,重复缺氧后虽然脑内Ａ１受体数目减少,但由于海马、脑桥和延髓处Ａ１受体的亲和力升高,累积增加的ＡＤＯ和Ａ１受体结合后,抑制神经细胞兴奋性的作用仍可能得到加强,从而使ＡＤＯ仍能更好地发挥抑制性神经调制作用。     

Changes of adenosine and its A(1) receptor in hypoxic preconditioning.

Effects of hypoxic preconditioning on adenosine (ADO) and its A(1) receptor were studied in Kunming mice. The ADO content and its metabolites in the brain were measured by a specific enzymatic method; a radioligand binding method was used to study the ADO A(1) receptor. The ADO content of the hippocampus in group C (exposure to 4 runs of hypoxia) was markedly higher than that in group A (control, without exposure to hypoxia and B (exposure to 1 run of hypoxia), showing that the ADO content could be cumulatively increased in the hippocampus, which was more sensitive to ischemia and hypoxia, during acute and repeated exposure to hypoxia. A(1) receptor density in group C was significantly lower than in group A and no difference was seen between groups B and C; A(1) receptor affinity in the hippocampus, pons and medula oblongata in group C was significantly higher than in group A, implying that during hypoxic preconditioning there might be some mechanisms preventing A(1) receptor density from decreasing further and making A(1) receptor affinity increase in some brain regions. These results indicate that cumulatively increased ADO in the hippocampus via A(1) receptor may play a neuroprotective role in the CNS as an inhibitory neuromodulator and thus contribute to the formation and development of acute hypoxic adaptation or tolerance.     

Activities of Five Different Sialyltransferases in Fish and Rat Brains

Abstract: To investigate the role of Sialyltransferases in the metabolism of brain gangliosides, we examined activities of five different Sialyltransferases (GM3-, GD3-, GT3-, GD1a-, and GT1a-synthase) using total membrane preparations from cichlid fish and Sprague-Dawley rat brains, and analyzed the relationship between the enzyme activities and the ganglloside compositions. The patterns of sialyltransferase activities in fish and rat brains differed from each other. In fish brain, the GM3-synthase activity was lower than GD3-synthase activity, whereas the opposite relationship was observed in rat brain. The GT3-synthase reaction with fish brain membranes produced radiolabeled GM3, GD3, and a ganglioside that was identified as GT3 based on mobility on TLC using two different solvent systems. No GT3-synthase activity was detected in rat brain. The GD1a-and GT1a-synthase activities in fish brain were higher than those in rat brain. Although GT1a was a single radiolabeled ganglioside in fish GT1a-synthase reaction, this ganglioside could not be detected in rat brain. The ratios of GM3-, GD3-, GT3-, GD1a-, and GT1a-synthase activities in fish and rat brain were 23:31:4:28:14 and 61:21:0:18:0, respectively. Ganglioside analysis showed that fish brain was enriched with c-series gangliosides including GT3 and polysialo-species, whereas a-and b-se-ries gangliosides were major components in rat brain. These results suggest that the species-specific expression of gangliosides in brain tissues may be regulated, at least in part, at the level of sialyltransferase activities.     

Acute adaptation of mice to hypoxic hypoxia.

Tolerance to hypoxia in vivo and in vitro was significantly increased by acute and repetitive exposure of mice to autoprogressive hypoxia. The average tolerance times of the successive 2nd, 3rd, 4th and 5th runs of exposure were, respectively, 2, 4, 6 and 8 times as long as that of the first exposure. The survival times under hypobaric chamber and cyanide toxification in the 4th exposure were, respectively, 10 (and even as much as 86) and 4 times those in control mice without exposure to hypoxia. Mandibular respiration and spinal reflex in vitro in hypoxia-resistant animals lasted 5-6 times as long as in control animals not previously exposed to hypoxia. Animals that received brain homogenate from hypoxia-resistant mice remained alive in a hypobaric chamber 2 times as long as those that received homogenate from controls and those that received saline. These results indicate that a kind of quickly developing adaptation with increased tolerance is achieved by acute and repetitive exposure of mice to progressive autohypoxia and some plastic or adaptive changes occur in the brain of hypoxia-resistant animals, including the production of some kind of water-soluble antihypoxic factors.     

Ganglioside-specific binding protein on rat brain membranes

A derivative of ganglioside GT1b (IV3NeuAc,II3(NeuAc)2-GgOse4) with an active ester in its lipid portion was synthesized and covalently attached to bovine serum albumin (BSA). The conjugate, having four GT1b molecules per albumin molecule [GT1b)4BSA) was radioiodinated and used to probe rat brain membranes for ganglioside binding proteins. A ganglioside-specific, high affinity (KD = 2-4 nM), saturable (Bmax = 13-20 pmol/mg membrane protein) binding site for 125I-(GT1b)4BSA was demonstrated on detergent-solubilized rat brain membranes adsorbed to filters. 125I-(GT1b)4BSA binding was tissue-specific (more than 35-fold greater to brain than to liver membranes) and was nearly eliminated by pretreatment of brain membrane-adsorbed filters with trypsin (1 microgram/ml). Underivatized gangliosides added as mixed detergent-lipid micelles blocked 125I-(GT1b)4BSA binding to brain membranes; structurally related GQ1b, GT1b, and GD1b were the most potent (half-maximal inhibition at 70-110 nM), while half-maximal inhibition by other gangliosides (GD3, GD1a, GM3, GM2, and GM1) required 5-20-fold higher concentrations. Other sphingolipids, neutral glycosphingolipids, and glycoproteins were poor inhibitors, and treatment of (GT1b)4BSA with neuraminidase attenuated its binding. Although most phospholipids were noninhibitory, phosphatidylinositol and phosphatidylglycerol inhibited half-maximally at 400-600 nM. However, inhibition of 125I-(GT1b)4BSA binding by gangliosides was competitive and reversible while that by phosphatidylinositol and phosphatidylglycerol was not. Ganglioside-protein conjugate binding reveals ganglioside-specific brain membrane receptors.     

Formation of Ganglioside GD 1b-Lactone in Rat Brain from Intracisternally Administered GD 1b

The presence of ganglioside GD1b, in lactone form GD1b-L, was ascertained in rat brain. The possible formation of GD1b-L from GD1b in brain was explored by the intracisternal injection of GD1b, 3H-labelled at the level of the terminal galactose. This was followed by recognition of the radioactive gangliosides formed at different times (1, 3, and 7 days) after injection. Whereas at 0 time after injection the only radioactive ganglioside was GD1b, after 1, 3, and 7 days other radioactive gangliosides were also found, thus indicating GD1b penetration into the brain tissue, followed by metabolic processing. Besides GD1b, the following radioactive gangliosides were recognized: GM1 and GM2, derived from GD1b degradation; GT1b, formed by the direct sialylation of GD1b; and GD1b-L, produced by metabolic lactonization. The radioactivity carried by GD1b-L was maximal 3 days after injection; its time course was different from that of the other gangliosides, suggesting that the process of lactonization is separate from that of both degradation and glycosylation. Under the same experimental conditions, some radioactive gangliosides also appeared in the liver, although in much smaller amounts than in brain. Radioactive GD1b-L could not be detected in liver, thus indicating that metabolic lactonization is a tissue- or organ-specific process.     

A monoclonal antibody reacting specifically with ganglioside GD1b in human brain

A mouse monoclonal antibody directed against one of the major human brain gangliosides, GD1b, has been produced. The antibody binds specifically to the carbohydrate structure of GD1b as it does not react with structurally related gangliosides like GM1, GD2, GT1b or Fuc-GM1, or any other ganglioside of human brain. The results further indicate that terminal galactose as well as the disialosyl group linked to the inner galactose moiety are involved in binding to the antibody.     

Gangliosides in various brain areas of three inbred strains of mice

The ganglioside patterns of cerebellum, cortex, pons-medulla, hypothalamus, hippocampus and caudate nucleus of three inbred strains of mice (C57BL/6J, DBA/2J and BALB/cJ) have been analysed. All brain areas contained both the simple and complex species of gangliosides. GD1a was the major ganglioside in cortex, hippocampus and caudate nucleus whereas GT1b was the major species in cerebellum, hypothalamus and pons-medulla. In hippocampus, the percentages of GT1b and GD1a were quite similar. Pons and medulla exhibited the highest levels of GM1 (which approaches the value of GT1b) and the lowest values of GD1a. A ganglioside, termed here GT1L, was located between GD1b and GT1b. This ganglioside, which was present in highest amounts in cerebellum disappeared after alkali treatment. Highly significant differences were observed in the amounts and patterns of gangliosides among brain areas of the three strains. Highly significant differences (p<0.001) were also found in the ganglioside distribution of various brain areas among the strains, especially for tri-and tetrasialogangliosides between Balb and DBA. A significant difference of GM1 was observed in the cerebellum when comparing DBA with the two other strains. It is likely that the differences might be related to their relative abundances in certain cell types and for defining synaptic circuits in brain areas of some strains.     

GANGLIOSIDE1−COMPOSITION OF BRAIN IN TAY-SACHS DISEASE: INCREASED AMOUNTS OF GD2 AND N-ACETYL-β-D-GALACTOSAMINYL GD1a GANGLIOSIDE

Abstract— The ganglioside composition of the brain of a patient with Tay-Sachs disease (TS-brain) was determined by a newly developed ganglioside-mapping procedure and compared with that of an age-matched control brain. GM2 ganglioside was the predominant component in TS-brain and the following gangliosides were also found, GM1, GD1a, GD1b and GT1 (major gangliosides in normal brain), and GM3, GD3, GD2 and GD1a-GAN (minor or undetectable components of normal brain). Individual gangliosides were isolated by column chromatography using a combination of DEAE-Sepharose, Iatrobeads and Silica Gel 60 and their structures were confirmed by comparing them with authentic standards using TLC, analysing their carbohydrate compositions by gas-liquid chromatography and cleaving them sequentially with glycosidases. The amounts of individual components were measured by quantitative densitometric scanning of the thin-layer plates. As a reflection of myelin breakdown, no sialosylgalactosyl ceramide was detectable in TS-brain. Although the total amounts of all gangliosides except GM2 in TS-brain were low, there were normal molar ratios of the main gangliosides in normal brain, that is, GM1, GD1a, GD1b and GT1. In comparison with the amount of GDla ganglioside, the amounts of GM2, GD2 and GD1a-GAN, which contain N-acetylgalactosamine as a terminal carbohydrate residue, were all elevated in TS-brain. The long chain bases of individual gangliosides contained both C-18 and C-20 sphingosine in different ratios and the ratio of C-20 to C-18 increased in the gangliosides in the order: GM2 < GM1 < GD1a < GD1a-GAN < GD1b < GT1 in both normal brain and TS-brain. In contrast, GD2 and GD3 gangliosides consisted mainly of C-18 sphingosine. The C-20 to C-18 ratios of individual gangliosides in the TS-brain were lower than those of age-matched control brain. Hexosaminidase from Turbo cornutus showed the same specific activity and K_m value in catalysing the cleavage of terminal N-acetylgalactosaminyl residues from GM2, GD2 and GD1a-GAN, suggesting that the brain gangliosides that increase in Tay-Sachs disease may be cleaved by the same enzyme.     

Ganglioside Composition in Human Meningiomas

The ganglioside composition in meningioma specimens from 20 patients was analyzed to find potential meningioma-associated structures. The characterization was performed by immunological staining with specific monoclonal antibodies to ganglioside antigens and fast atom bombardment-mass spectrometry. The major gangliosides were GM3 and GD3, and most of the meningioma specimens could be divided into a "GM3-rich" or a "GD3-rich" group. Gangliosides of the gangliotetraose series were represented by GM1, GD1a, GD1b, and GT1b, which were found in minor amounts in all the specimens. The ratios of GM1/GD1a and GD1a/GD1b differed from that in normal brain, and therefore existence of this series could not be explained by contamination with brain material. Ganglioside 3'-isoLM1, found in human malignant glioma, could not be detected in any meningioma specimen.