脱辅基脂蛋白E(ApoE)及低密度脂蛋白(LDL)受体在外周神经中的双向运输

本文用免疫细胞化学法研究正常和再生的大白鼠外周神经中脱辅基脂蛋白E(ApoE)和低密度脂蛋白(LDL)受体的运输特性,发现在正常的外周神经中,ApoE及LDL受体在轴浆中均可沿轴突正行和逆行运输;再生的神经可产生ApoE,ApoE可逆行向细胞体转运。ApoE及LDL受体运输特性的研究为ApoE及LDL受体参与神经损伤后的修复和再生提供了进一步的证据。     

大白鼠脑中表达低密度脂蛋白(LDL)受体的神经元可吸收含脱辅基蛋白E(ApoE)的脂蛋白

用组织荧光和免疫细胞化学相结合法研究含脱辅基蛋白E(ApoE)的脂蛋白是否可被中枢神经元所吸收。实验结果如下: 1.含ApoE的脂蛋白仅被注射针迹附近的神经元所吸收。 2.只有表达出低密度脂蛋白(LDL)受体的神经元才能吸收含ApoE的脂蛋白。 3.不能表达LDL受体的神经元不能吸收含ApoE的脂蛋白。 实验结果表明,含ApoE的脂蛋白、LDL受体的表达及ApoE-LDL受体的相互作用是哺乳动物中枢神经系统内实现胆固醇运输和维持胆固醇代谢平衡的重要机制。     

大白鼠脑中表达低密度脂蛋白(LDL)受体的神经元可吸收含脱辅基蛋白E(ApoE)的脂蛋白

用组织荧光和免疫细胞化学相结合法研究含脱辅基蛋白E(ApoE)的脂蛋白是否可被中枢神经元所吸收。实验结果如下: 1.含ApoE的脂蛋白仅被注射针迹附近的神经元所吸收。 2.只有表达出低密度脂蛋白(LDL)受体的神经元才能吸收含ApoE的脂蛋白。 3.不能表达LDL受体的神经元不能吸收含ApoE的脂蛋白。 实验结果表明,含ApoE的脂蛋白、LDL受体的表达及ApoE-LDL受体的相互作用是哺乳动物中枢神经系统内实现胆固醇运输和维持胆固醇代谢平衡的重要机制。     

胶质细胞系来源的神经营养因子家族配体研究现状

胶质细胞系来源的神经营养因子家族配体(GFLs)通过受体酪氨酸激酶激活靶细胞内特定的信号转导途径,从而促进多种外周和中枢发育神经元的存活、再生、损伤修复及生长和分化,并维持其正常功能,保证神经元间的正确连接。     

低密度脂蛋白受体研究进展

低密度脂蛋白(LDL)受体的研究进一步揭示了细胞外大分子在细胞内进行代谢调节的详细途径,对脂代谢具有重要意义。本文从LDL受体的生物学特性、存在部位、在完整机体的功能以及LDL受体与高脂血症及动脉粥样硬化病变的关系等方面综述了近年来的研究进展。     

猴肝细胞膜脂蛋白(a)受体的研究

猴肝细胞膜蛋白经 SDS- PAGE和蛋白转移电泳后用免疫印迹法测定 ,硝酸纤维素膜分别与抗牛肾上腺皮质 LDL受体的抗体、LDL、Lp( a)和 PLG温育后见有 3条不同的蛋白条带 ,分子量分别为 370 kd、2 90 kd和 80 kd.用酶标法测定猴肝细胞膜蛋白 ,发现经 Lp( a) + PLG温育后用 Lp( a)抗体反应的结果与 Lp( a)温育后用 Lp( a)抗体反应的结果比较无显著差异 ,而经 Lp( a) + PLG温育后用 PLG抗体反应的结果比单独用 PLG温育后用 PLG抗体反应的作用强 ;同样经 Lp( a) +LDL温育后用 Lp( a)抗体反应的结果与经 Lp( a)温育后用 Lp( a)抗体反应的结果比较无显著差异 ,而经 Lp( a) + LDL温育后用 LDL抗体反应比单独经 LDL温育后用 LDL抗体的反应强 ,排除Lp( a)与 PLG和 LDL的交叉反应 ,实验认为猴肝细胞膜上可能同时存在 LDL受体、PLG受体和Lp( a)受体     

大白鼠交感节前神经再生的研究Ⅰ.生化、组化与功能观察

用液氮骤冻造成大白鼠交感节前神经变性后,通过神经末梢乙酰胆碱含量、胆碱酯酶活性测定以及电刺激交感干时外周反应等研究其再生规律。结果表明冻伤后3周内再生过程进展迅速,神经结构与功能均有相当程度的恢复;3周后再生过程转慢,直至一年时各指标仍远未达到正常。这证明交感节前神经的再生过程不同于中枢及其它外周神经而独具特征。     

基因修饰小鼠在脂代谢紊乱与动脉粥样硬化研究中的新进展

近十余年来,载脂蛋白(ApoE)与低密度脂蛋白(LDL)受体 (LDLr)基因敲除小鼠已成为研究脂代谢和动脉粥样硬化最为常用的模型.在这两种小鼠模型基础上,通过与不同的转基因、基因敲除小鼠杂交,产生了多种脂代谢紊乱和动脉粥样硬化小鼠模型,为发现调控血浆脂蛋白以及动脉粥样硬化发生的机制,创造了有利条件.此外,新的严重高甘油三酯血症小鼠模型也制备成功,本文笔者研究组研究了其中的脂蛋白脂酶缺陷模型与代谢性疾病的关系,得到了许多有意义的结果.而利用不同转基因和去基因小鼠作为供体, 以及ApoE或LDL受体缺陷小鼠作为接受体的骨髓移植技术,则大大丰富了人们对于巨噬细胞中不同基因在动脉粥样硬化发生、发展和消退过程中作用的认识.动脉粥样硬化的易损斑块形成是近年来的一个研究热点,应用小鼠模型进行模拟也取得了一定的成功.然而,小鼠与人类在脂代谢和动脉粥样硬化中存在很大的种系差异,本文对此也予以评述.     

Galanin(甘丙肽)及其受体在成年小鼠脑内神经新生部位的表达及对神经干细胞分化的作用

Galanin(甘丙肽)是一种在中枢神经系统中广泛分布的神经肽,功能涉及摄食、睡眠和觉醒、疼痛、认知和生殖等各方面.我们在成年小鼠脑的神经细胞新生部位如SVZ,DG和RMS发现有galanin及其受体的mRNA表达,同时在SVZ来源的神经干细胞中也检测到有galanin及其受体的表达.细胞实验中,在分化后特定时间段GALKO小鼠来源的神经干细胞产生神经突的细胞比例及神经突的长度明显小于正常小鼠来源的神经干细胞.而加入galanin或受体激动剂GAL2-11后.该神经干细胞则在产生神经突的细胞比例及神经突的长度都明显上升.受体拮抗剂M35的添加可减弱galanin或GAL2-11所产生的作用.这些结果表明galanin及其受体与神经干细胞的分化及神经突的生长有着密切的联系,并可能参与了神经系统的发育.     

戊巴比妥对大鼠骨胳肌辣根过氧化物酶(HRP)的轴突摄取和逆行传送作用

腓肠肌内注射HRP后,用生物化学法测定坐骨神经、L_(4-6)节段背根和腹根神经的HRP含量。在戊巴比妥连续全身麻醉大鼠的HRP含量明显低于不麻醉的大鼠,而肌肉不活动(TTX中毒和切腱)大鼠神经组织中的HRP含量无甚变化。刺激神经不能改变麻醉大鼠的HRP含量。上述结果提示:除麻醉剂造成的肌肉不活动因素外,戊巴比妥对大鼠骨胳肌HRP的轴突摄取和逆行传送具有另外的抑制作用。已有研究报道:破伤风和单纯性疱疹病毒脑炎都是由于它们的毒素或病毒,通过外周神经摄取然后逆行传送到各级中枢而致病的。     

S-nitrosylation of ApoE in Alzheimer's disease

The mechanism by which apolipoprotein E (ApoE) isoforms functionally influence the risk and progression of late-onset Alzheimer's disease (LOAD) remains hitherto unknown. Herein, we present evidence that all ApoE isoforms bind to nitric oxide synthase 1 (NOS1) and that such protein-protein interaction results in S-nitrosylation of ApoE2 and ApoE3 but not ApoE4. Our structural analysis at the atomic level reveals that S-nitrosylation of ApoE2 and ApoE3 proteins may lead to conformational changes resulting in the loss of binding to low-density lipoprotein (LDL) receptors. Collectively, our data suggest that S-nitrosylation of ApoE proteins may play an important role in regulating lipid metabolism and in the pathogenesis of LOAD.     

Low density lipoprotein receptors on epithelial cell (Madin-Darby canine kidney) monolayers. Asymmetric distribution correlates with functional difference

Low density lipoprotein (LDL) receptors are present on both the apical and basal surfaces of confluent monolayers of Madin-Darby canine kidney (MDCK) epithelial cells grown on gelatin-coated polycarbonate filters. Although there is only a single species of receptor protein present, as shown by immunoblotting, the receptors on the two surfaces were found to behave differently. LDL receptors on the basal surface show all of the characteristics of the LDL receptor described in fibroblasts in that their number is dependent upon the sterol (or LDL) content of the medium; however, regulation is only affected by LDL in the medium in contact with the basal side. In contrast, the apical surface LDL receptors are not regulated by the presence of LDL in the media on either the apical or basal surface. LDL particles can be transported across the monolayer in a temperature-dependent and -specific manner from the apical to the basal sides of the cell, but not in the opposite direction. The binding of 125I-LDL to both surfaces can be effectively inhibited not only by unlabeled LDL and very low density lipoprotein, but also by an antibody directed against the LDL receptor. The data suggest that the LDL receptors on the two aspects of the cell surface are biochemically identical, but differ in function. Thus, the basal surface receptor is involved in the control of cell cholesterol homeostasis, while that on the apical surface is responsible for the transport of LDL to the basal side.     

Rapid transport of internalized P-selectin to late endosomes and the TGN: roles in regulating cell surface expression and recycling to secretory granules

Prior studies on receptor recycling through late endosomes and the TGN have suggested that such traffic may be largely limited to specialized proteins that reside in these organelles. We present evidence that efficient recycling along this pathway is functionally important for nonresident proteins. P-selectin, a transmembrane cell adhesion protein involved in inflammation, is sorted from recycling cell surface receptors (e.g., low density lipoprotein [LDL] receptor) in endosomes, and is transported from the cell surface to the TGN with a half-time of 20-25 min, six to seven times faster than LDL receptor. Native P-selectin colocalizes with LDL, which is efficiently transported to lysosomes, for 20 min after internalization, but a deletion mutant deficient in endosomal sorting activity rapidly separates from the LDL pathway. Thus, P-selectin is sorted from LDL receptor in early endosomes, driving P-selectin rapidly into late endosomes. P-selectin then recycles to the TGN as efficiently as other receptors. Thus, the primary effect of early endosomal sorting of P-selectin is its rapid delivery to the TGN, with rapid turnover in lysosomes a secondary effect of frequent passage through late endosomes. This endosomal sorting event provides a mechanism for efficiently recycling secretory granule membrane proteins and, more generally, for downregulating cell surface receptors.     

Apolipoproteins and atherosclerosis. Apolipoprotein E and apolipoprotein(a) as candidate genes of premature development of atherosclerosis

Apolipoprotein E (apoE) is a plasma lipoprotein which plays a basic role in the degradation of particles rich in cholesterol and triglycerides. It is able to bind to LDL receptors, but also to receptors for chylomicron remnants. There are three major apoE isoforms, E2, E3, and E4. Their role in lipoprotein metabolism is related to their affinity for receptors. Allele E3 is predominant and apoE3 affects metabolism of lipoproteins in a standard way. When compared to allele E3, allele E2 is associated with lower LDL levels, whereas allele E4 with higher LDL levels. This has an impact on the progression of atherosclerosis. Allele E2 exhibits a protective role, whereas allele E4 is associated with a high risk factor. Lipoprotein(a) [Lp(a)] is a plasma lipoprotein, consisting of apolipoprotein(a), linked by a covalent bond with the LDL particle. Increased Lp(a) levels are associated with an increased incidence of diseases based on atherosclerosis, namely the ischemic heart disease. Another effect of Lp(a) is its competition with plasminogen, resulting in a decrease of fibrinolysis and thrombogenic activity. ApoE and Lp(a) are independent risk factors for premature development of atherosclerosis and therefore can be considered as candidate genes of premature atherosclerosis.     

Retrograde transport of nerve growth factor (NGF) in motoneurons of developing rats: assessment of potential neurotrophic effects

The potential functional significance of nerve growth factor (NGF) receptors in spinal motoneurons was studied in newborn rats. 125I-NGF was specifically retrogradely transported by motoneurons from their peripheral nerve terminals. This transport was blocked by an excess of unlabeled NGF but not by cytochrome c. 125I-cytochrome c was not transported. The monoclonal anti-rat NGF receptor antibody, but not a control antibody, was also transported. Despite this ability of motoneurons to transport NGF, treatment of newborn rats with this factor did not increase motoneuron size or synthesis of neurotransmitter enzymes and did not prevent cell death after axotomy. We conclude that NGF receptors of spinal motoneurons can bind, internalize, and retrogradely transport NGF. However, these receptors do not mediate the classic trophic effects of NGF.     

Apolipoprotein E activates Akt pathway in neuro-2a in an isoform-specific manner

Apolipoprotein E (apoE) is a ligand for members of the low density lipoprotein (LDL) receptor family, receptors highly expressed in neurons. A study of one of the mechanisms by which apoE might affect neuronal cell metabolism is reported herein. ApoE can induce Akt/protein kinase B phosphorylation in Neuro-2a via two different pathways. Both pathways are mediated by phosphatidylinositol 3-kinase and cAMP-dependent protein kinase. The first pathway is stimulated by apoE3 and E4, but not by E2, after a 1-h incubation. The process requires the binding of apoE to the heparan sulfate proteoglycan/LDL receptor-related protein complex. The second pathway is activated after a 2-h incubation of the cells, in another isoform-dependent manner (E2 = E3 dbl greater-than sign E4) and is mediated by calcium. Our results suggest that apoE might affect cell metabolism and survival in neurons in an isoform-specific manner by inducing novel signaling pathways.     

Transport of lipids from high and low density lipoproteins via scavenger receptor-BI.

The scavenger receptor-BI (SR-BI) delivers sterols from circulating lipoproteins to tissues, but the relative potency of individual lipoproteins and the transported cholesterol has not been studied in detail. In this study, we used Chinese hamster ovary cells that express recombinant mouse SR-BI but have no functional low density lipoprotein (LDL) receptors (ldlA7-SRBI cells) to compare the fate of lipids transferred from high or low density lipoproteins to cells by SR-BI. HDL and LDL were equally effective in mediating the transfer of [(3)H]cholesterol to cells. Only 5% of the free cholesterol transferred to cells was esterified, in direct contrast to the findings in the cells that express LDL receptors in which 50% of the transported cholesterol was esterified. Almost all the free cholesterol transferred from lipoproteins to cells was rapidly excreted when the ldlA7-SRBI cells were switched to media containing unlabeled lipoproteins. SR-BI expression was associated with an increase in selective cholesteryl ester uptake from both lipoproteins, but HDL was a more effective donor. HDL and LDL were equally effective in delivering cholesterol to the intracellular regulatory pool via SR-BI. These data indicate that SR-BI is able to exchange cholesterol rapidly between lipoproteins and cell membranes and can mediate the uptake of cholesteryl esters from both classes of lipoproteins.     

Antitumor photochemotherapy: biochemical bases, therapeutic uses and perspectives]

The photodynamic therapy of tumors (PDT) is a recent and promising technique for the treatment of tumors which can be reached by the light (directly or by endoscopic illumination). Excellent results are now obtained with hematoporphyrin derivatives such as Photofrin II, provided the concerned tumors are small and well delimited. Porphyrins are transported in blood mainly by lipoproteins, and the low density lipoprotein (LDL) receptor-mediated pathway is probably one of the important factors involved in the selective accumulation of porphyrins by tumor tissues, as cancer cells generally express much more LDL receptors than normal cells. In the present paper, after a brief presentation of the biochemical basis of the light-dependent cytotoxicity of porphyrins, we shall examine the role of lipoproteins, especially LDL, in the transport and the cellular uptake of these compounds. We shall also present recent approaches for the improvement of the PDT efficiency.     

Cellular catabolism of lipid poor apolipoprotein E via cell surface LDL receptor-related protein

Apolipoprotein E (apoE), an apoprotein involved in lipid transport in both the plasma and within the brain, mediates the binding of lipoproteins to members of the low density lipoprotein (LDL) receptor family including the LDL receptor and the LDL receptor-related protein (LRP). ApoE/LRP interactions may be particularly important in brain where both are expressed at high levels, and polymorphisms in the apoE and LRP genes have been linked to AD. To date, only apoE-enriched lipoproteins have been shown to be LRP ligands. To investigate further whether other, more lipid-poor forms of apoE interact with LRP, we tested whether lipid-free apoE in the absence of lipoprotein particles interacts with its cell-surface receptors. No detectable lipid was found associated with bacterially expressed and purified apoE either prior to or following incubation with cells when analyzed by electrospray ionization mass spectrometry. We found that the degradation of lipid-poor (125)I-apoE was significantly higher in wild type as compared to LRP-deficient cells, and was inhibited by receptor-associated protein (RAP). In contrast, (125)I-apoE-enriched beta-VLDL was degraded by both LRP and the LDL receptor. When analyzed via a single cycle of endocytosis, (125)I-apoE was internalized prior to its subsequent intracellular degradation with kinetics typical of receptor-mediated endocytosis. Thus, we conclude that a very lipid-poor form of apoE can be catabolized via cell surface LRP, suggesting that the conformation of apoE necessary for recognition by LRP can be imposed by situations other than an apoE-enriched lipoprotein.