外源性神经节苷脂相关性吉兰—巴雷综合征的发病机制及诊治研究进展

吉兰―巴雷综合征（GBS）是一种以快速进行性四肢麻木无力为特点的急性炎性脱髓鞘性多发性多神经根神经病。随着外源性神经节苷脂在临床的广泛应用，该药引起的副作用也逐渐显现，外源性神经节苷脂相关性GBS是其最严重的并发症，临床上主要表现为轴索型GBS，以四肢弛缓性瘫痪为首发症状，表现为急性、严重且快速进展的周围神经受累，较其他轴索型GBS病情重，恢复时间长，预后差。目前发病机制尚不明确。静脉注射人免疫球蛋白是其具有循证医学证据的治疗方法，目前已取代血浆置换成为GBS首选治疗方法，推荐剂量为0.4 g/（kg·d），连续静滴5 d，大剂量激素治疗的效果还有待进一步探讨。早发现、早诊断、尽早停用外源性神经节苷脂、及时应用人血免疫球蛋白冲击治疗和康复治疗，可改善预后。     

Chronic opioid treatment of neuroblastoma X dorsal root ganglion neuron hybrid F11 cells results in elevated GM1 ganglioside and cyclic adenosine monophosphate levels and onset of naloxone-evoked decreases in membrane K+ currents

Prolongation of the action potential duration of dorsal root ganglion (DRG) neurons by low (nM) concentrations of opioids occurs through activation of excitatory opioid receptors that are positively coupled via G_s regulatory protein to adenylate cyclase. Previous results suggested GM1 ganglioside to have an essential role in regulating this excitatory response, but not the inhibitory (APD-shortening) response to higher (μM) opioid concentrations. Furthermore, it was proposed that synthesis of GM1 is upregulated by prolonged activation of excitatory opioid receptor functions. To explore this possibility we have utilized cultures of hybrid F11 cells to carry out closely correlated electrophysiological and biochemical analyses of the effects of chronic opioid treatment on a homogeneous population of clonal cells which express many functions characteristic of DRG neurons. We show that chronic opioid exposure of F11 cells does, in fact, result in elevated levels of GM1 as well as cyclic adenosine monophosphate (AMP), concomitant with the onset of opioid excitatory supersensitivity as manifested by naloxone-evoked decreases in voltage-dependent membrane K⁺ currents. Such elevation of GM1 would be expected to enhance the efficacy of excitatory opioid receptor activation of the G_s/adenylate cyclase/cyclic AMP system, thereby providing a positive feedback mechanism that may account for the remarkable supersensitivity of chronic opioid-treated neurons to the excitatory effects of opioid agonists as well as antagonists. These in vitro findings may provide novel insights into the mechanisms underlying naloxone-precipitated withdrawal syndromes and opioid-induced hyperalgesia after chronic opiatf addiction in vivo. © 1995 Wiley-Liss, Inc.     

Cholera Toxin B-Mediated Targeting of Lipid Vesicles Containing Ganglioside GM1 to Mucosal Epithelial Cells

Purpose. To determine whether the non-toxic pentameric B subunit of Cholera toxin (CTB) binding to ganglioside GM1 on both the lipid vesicles and epithelial cells may provide a means to target lipid vesicles to mucosal cells expressing surface GM1. Methods. Sonicated lipid vesicles containing ganglioside GM1 were prepared. Inter-vesicle cross-linking due to pentameric CTB binding to these GM1 vesicles was determined with a sub-micron particle analyzer. Association of CTB to GM1 vesicles was analyzed with continuous sucrose gradient centrifugation. CTB-mediated binding of GM1 vesicles to human mucosal epithelial cells (Caco-2 and HT-29), mucous membranes of mouse trachea, and nasal tissues were detected with fluorescent labeled vesicles. Results. An increase in lipid particle size due to binding of CTB to lipid vesicles and inter-vesicles cross-linking was detected. At a 30-to-1 mole ratio of membrane-bound GMl-to-CTB, optimum increase in GM1 vesicle aggregation, was detected. Under such conditions, all the added CTB molecules were associated with GM1 vesicles. Time course analysis showed that inter-vesicles cross linking by CTB was detectable within 10 min. and reached a maximum value at 60 min. CTB associated GM1-vesicles bind to mucosal epithelial cells HT-29 and Caco-2 with similar affinity [K_d = 7.8 × 10^–4 M lipid (Caco-2) and 7.6 × 10^–4 M lipid (HT-29)]. GM1 mediated binding specificity was demonstrated by blocking with anti-GMl antibody and the insignificant degree of CTB-associated GM1 vesicle binding to GM1 deficient C6 cells. Conclusions. The CTB-mediated GM1 binding to multiple membrane surfaces provides selective localization of GM1 vesicles to GM1 expressing mucosal cells and tissues. The strategy may be useful in localizing drugs and proteins to gut and respiratory tract mucosa.     

Anti-gal-C antibody in autoimmune neuropathies subsequent to mycoplasma infection

Four of 82 patients with Guillain-Barré syndrome (GBS) and 1 of 12 with multifocal motor neuropathy (MMN), who previously had had Mycoplasma pneumoniae infections, had serum antibody to galactocerebroside (Gal-C). Two patients with GBS without mycoplasma infection also had anti-Gal-C antibody, whereas none of the normal or the disease controls had it. As Gal-C is a major glycolipid antigen in myelin, anti-Gal-C antibody may function in the pathogenesis of autoimmune demyelinative neuropathies. Mycoplasma pneumoniae appears to be an important preceding infectious agent in autoimmune neuropathies with anti-Gal-C antibody. © 1995 John Wiley & Sons, Inc.     

GM1 ganglioside partially rescues cultured dopaminergic neurons from MPP-induced damage: dependence on initial damage and time of treatment

GM1 ganglioside is believed to be important in promoting the recovery of neurons from injury. The present study assesses the ability of GM1 to repair or prevent the damage of dopamine neurons caused by the neurotoxin 1-methyl-4-phenylpyridinium (MPP⁺). Treatment of mesencephalic cell cultures with 2.5 μM MPP⁺ resulted in the loss of 30% of tyrosine hydoxylase (TH) immunoreactive neurons. In contrast, cultures administered 100 μM GM1 ganglioside for 3 days after toxin treatment contained nearly control numbers of TH⁺ neurons (97%). This reparative effect of GM1 was reflected in parallel increases in TH enzyme activity, dopamine and dopac levels. Cultures sustaining greater insult from higher doses of MPP⁺ (5.0–10.0 μM) did not benefit from ganglioside treatment, suggesting that rescue by GM1 depended on the degree of initial damage to cells. Moreover, the timing of ganglioside treatment was critical; pretreatment with GM1 alone did not prevent or attenuate the damage caused by subsequent incubation in 2.5 μM MPP⁺.     

Enhancement of liver cell proliferation by GM3 ganglioside

In experiments on rats subjected to partial hepatectomy and experimentally induced hepatitis it is shown that GM₃ ganglioside of equine erythrocytes can enhance liver cell proliferation. The effect was also observed in experiments on a primary hepatocyte culturein vitro; moreover, enhancement of cell proliferation did not depend on the type of sialic acid residues. Translated fromByulleten' Eksperimental'noi Biologii i Meditsiny, Vol. 119, N ^o 4, pp 427–430, April, 1995     

In vivo and in vitro effects of melatonin or ganglioside GT1B on L-cysteine-induced brain mitochondrial DNA damage in mice.

The effects of L-cysteine on mitochondrial DNA (mtDNA) in mouse brain were investigated both in vivoandin vitro. An intracerebroventricular (icv) injection of L-cysteine (1.25 micromol/animal) caused mtDNA damage in brain frontal and central portions of the cortex, broad-spectrum limbic and severe sustained seizures in mice, and increased lipid peroxidation in the whole brain. The L-cysteine-mediated effects were prevented by an intraperitoneal (ip) preinjection of melatonin (20 mg/kg) or an intracerebroventricular preinjection of ganglioside GT1b (90 nmol/animal). Furthermore, in in vitroexperiments, L-cysteine (0.05, 0.5, or 1.0 mM) caused damage to brain mtDNA and increased lipid peroxidation in a concentration-dependent manner when incubated at 37 degrees C for 20 or 60 min with a homogenate prepared from whole mouse brains. However, the mtDNA damage and the increased lipid peroxidation were completely abolished by a cotreatment with melatonin (1.5 mM), a potent scavenger of the hydroxyl radical (*OH), or ganglioside GT1b (60 microM), a potent inhibitor of glutamate-receptor-mediated activation and translocation of protein kinase C and lipid peroxidation. These results suggest that reactive oxygen species including the *OH may be involved in l-cysteine-induced brain mtDNA damage, lipid peroxidation, and development of seizures in mice. Therefore, we concluded that *OH scavengers, such as the pineal hormone melatonin and ganglioside GT1b, can protect against brain mtDNA damage, seizures, and lipid peroxidation induced by reactive oxygen species producers such as L-cysteine.     

A rat model of leptomeningeal human neoplastic xenografts

Leptomeningeal (LM) cancer spread from either a primarybrain tumor or a systemic cancer is rapidlyfatal. Current therapies are ineffective and highly toxicto normal nervous system tissues. A xenograft modelof LM neoplasia in nude rats using adiversity of tumor cell types was established inorder to evaluate new treatment strategies and tostudy the pharmacokinetics and biological effects of treatmentsadministered into the subarachnoid space. Consistent leptomeningeal engraftmentand progressive tumor growth was seen after intrathecalinjection of 9 of 13 tumor cells lines,including 2 melanomas, 2 neuroblastomas, 2 medulloblastomas, 2gliomas, and 1 breast cancer. Clinical signs rangedfrom steady weight loss commencing from the dayafter tumor implantation to absence of any signsfor three weeks until the sudden occurrence ofmajor neurological deficits or death. Pathologic examination showedonly leptomeningeal tumor growth with some cell linesand severe parenchymal invasion with others. CSF cytologyconsistently demonstrated tumor cells in animals with LMdisease. Cranial magnetic resonance (MR) following intravenous (IV)administration of a contrast agent revealed enhancing lesionsone week following melanoma tumor implantation. Reliable ventricularpuncture was demonstrated by radiography following intraventricular (IVent)injection of an iodinated contrast material. IVent instillationof saline, albumin, or antibodies did not provokeclinical toxicity or an inflammatory response.     

Enhanced Tumor Targeting of Doxorubicin by Ganglioside GMl-bearing Long-circulating Liposomes

Abstract

Doxorubicin (DXR) was encapsulated in long-circulating liposomes, composed of ganglioside GM1 (GM1)/distearoylphosphatidylcholine (DSPC)/cholesterol (CH) (0.13:1:1 in molar ratio) and sized to approximately 100 nm in mean diameter, with 98% entrapping efficiency by the transmembrane pH gradient method. Free DXR, DXR-DSPC/CH and DXR-GM1/DSPC/CH liposomes were injected intravenously into Colon 26 tumor-bearing Balb/c mice via the tail vein at a dose of 5.0 mg DXR/kg. DXR-GM1/DSPC/CH liposomes gave a higher blood level of the drug than did DXR-DSPC/CH liposomes or free DXR up to 24 hours after injection, and the area under the blood concentration-time curve (AUC) for DXR-GM1/DSPC/CH liposomes was 1.5 or 526 times higher than that for DXR-DSPC/CH liposomes or free DXR, respectively. DXR-GM1/DSPC/CH liposomes gave a decreased DXR concentration in the reticuloendothelial system (RES) of the liver and the spleen. Both liposomal formulations effectively reduced the DXR concentration in the heart as compared with that in the case of free DXR. At 6 hours after i.v. injection, DXR-GM1/DSPC/CH liposomes provided an approximately 3.3- or 9-fold higher peak DXR level in the tumor as compared with DXR-DSPC/CH liposomes or the free drug, respectively. These high tumor levels of DXR appear to reflect the prolonged residence time of the liposomes. The results suggest that encapsulation of DXR in GM1-bearing long-circulating liposomes will be useful for cancer chemotherapy.     

Sphingomyelin changes in rat cerebral cortex during focal ischemia

Abstract

To better define the sphingolipid metabolism during focal brain ischemia, levels of ceramide, sphingomyelin, cerebroside and gangliosides were determined in rat cerebral cortex during focal ischemia produced by occlusion of the middle cerebral artery. Sphingomyelin began to decrease at 2 hours of ischemia and continued to decrease for 96 hours. In contrast, ceramide increased at 6 hours and increased to 4.2-fold at 96 hours after ischemia, and the fatty acid composition of ceramide was solely nonhydroxylated fatty acid similar to sphingomyelin. Hydroxylated fatty acid-linked cerebroside decreased at 6 hours of ischemia, whereas any significant decrease of nonhydroxylated fatty acid-linked cerebroside didn't occur for 96 hours of ischemia. There were no measurable changes in the levels of gangliosides. These results suggested that ceramide was produced in the cerebral cortex by the breakdown of sphingomyelin during early ischemia. [Neurol Res 1996; 18: 337-341]