Summary

一个<em>体外</em>急性脑片的少突胶质细胞定向T细胞攻击模式

Published: February 05, 2015
doi:

Summary

To address mechanisms of demyelination and neuronal apoptosis in cortical lesions of inflammatory demyelinating disorders, different animal models are used. We here describe an ex vivo approach by using oligodendrocyte-specific CD8+ T-cells on brain slices, resulting in oligodendroglial and neuronal death. Potential applications and limitations of the model are discussed.

Abstract

Death of oligodendrocytes accompanied by destruction of neurons and axons are typical histopathological findings in cortical and subcortical grey matter lesions in inflammatory demyelinating disorders like multiple sclerosis (MS). In these disorders, mainly CD8+ T-cells of putative specificity for myelin- and oligodendrocyte-related antigens are found, so that neuronal apoptosis in grey matter lesions may be a collateral effect of these cells. Different types of animal models are established to study the underlying mechanisms of the mentioned pathophysiological processes. However, although they mimic some aspects of MS, it is impossible to dissect the exact mechanism and time course of ‘‘collateral’’ neuronal cell death. To address this course, here we show a protocol to study the mechanisms and time response of neuronal damage following an oligodendrocyte-directed CD8+ T cell attack. To target only the myelin sheath and the oligodendrocytes, in vitro activated oligodendrocyte-specific CD8+ T-cells are transferred into acutely isolated brain slices. After a defined incubation period, myelin and neuronal damage can be analysed in different regions of interest. Potential applications and limitations of this model will be discussed.

Introduction

Death of oligodendrocytes and destruction of the myelin sheath accompanied by loss of neurons and axons are typical pathological findings in grey matter lesions in individuals suffering from multiple sclerosis (MS)1,2. Cortical lesions can be divided so far in three different subtypes2: subpial, intracortical and leukocortical lesions. In comparison to white matter plaques, infiltrates are characterized by a predominance of CD8+ T-cells, suggesting their possible decisive role in grey matter inflammation3. Furthermore, oligoclonal expansions in blood, cerebrospinal fluid (CSF) and within inflammatory lesions can be found for CD8+ T-cells themselves4-6.

In line with this, it is assumed that CD8+ T-cells may be specific for different myelin proteins7,8. Indeed, CD8+ T-cells are found near oligodendrocytes and myelin sheaths9,10 that show MHC I expression11 and might therefore be responsible for the loss of the myelin sheath. This process is often seen together with extensive ‘‘collateral’’ neuronal and axonal damage within the central nervous system (CNS) grey matter1,2. In fact, direct and indirect death of oligodendrocytes and neurons is induced by CD8+ T-cells via two different mechanism: (i) cell membrane swelling and rupture due to the formation of cytotoxic granules following the release of perforins and granzymes and (ii) ligation to the Fas receptors or exposition of FasL on their surface8,12,13.

Different types of animal models are established to study the underlying mechanism of the mentioned processes. In this respect, primed CD8+ T-cells specific for autoantigens with induced expression in CNS glial cells, like oligodendrocytes or astrocytes, can be adoptively transferred to analyse ‘‘collateral’’ neuronal and axonal death in grey matter subsequently14,15. To perform such in vivo experiments is a big help to mimic some pathophysiological aspects of MS, however, this approach is not suited to resolve the underlying mechanism and kinetics of axonal damage and neuronal apoptosis.

To overcome these restrictions, an ex vivo approach was established to study the mechanisms and time course of neuronal cell death following a oligondendrocytes-directed CD8+ T-cell attack. Since only oligodendrocytes and therefore myelin sheath production should be targeted by immune cells, MHC class-I-restricted, ovalbumin (OVA)-reactive OT-I Tcells are used16. These cells are subsequently transferred into brain slices obtained from mice selectively expressing OVA in oligodendrocytes (ODC-OVA mice)17.

Protocol

使用小鼠所有实验应根据各自的机构动物护理和使用委员会的指导方针进行。 1.一般注释小鼠实验保持小鼠无病原体的条件下,使它们获得食物和水随意。 注:由于免疫模式可以与年龄和性别的不同是非常重要的使用年龄和性别匹配的小鼠实验组。 2.制备和活化的OVA特异性CD8 + T细胞(OT-I) 为准备脑片之前描述如下5天执…

Representative Results

脑切片与少突胶质细胞定向的CD8 + T细胞的培养后,少突胶质细胞以及神经元凋亡( 图2A和图1C,分别)。 ( 例如,胱天蛋白酶-3,TUNEL)可以最早3小时孵育后检测细胞凋亡的组织学迹象。潜伏期不应该长于8小时,以保证在制备和可再现的结果的一个良好的品质。细胞凋亡,可以发现全国各地有优势的领域髓切片。片的结构的完整性和凋亡神经元的示例性组织染色中描?…

Discussion

不同的动物模型已经描述在过去的几十年来解决的炎性脱髓鞘疾病如MS的病理特征。 体内小鼠和大鼠模型被广泛用于模拟疾病的病理生理特征,即,脱髓鞘和髓鞘再生过程的后果分析和炎症和神经退行性疾病的混合体发作。然而,只有一个离体方法允许解剖确切基本机制。

也是急性脑切片制备一个广泛分布的模型,并可以被认为是可靠的和可复制的。在与隔离?…

Declarações

The authors have nothing to disclose.

Acknowledgements

This work was supported by the Interdisciplinary Center for Clinical Research (IZKF) Münster (SEED 03/12, SB), Deutsche Forschungsgemeinschaft (SFB TR128, TP B6 to S.G.M. ME3283/2-1 to S.G.M.) and by Innovative Medizinische Forschung, Münster (I-BI111316, SB and SGM).

Materials

Name of Material/ Equipment Company Catalog Number Comments/Description
12-Well-plate Corning 3513
2-Mercaptoethanol Gibco 31350-010
2-Methylbutan Roth 3927.1
70 µm strainer Falcon 352350
CaCl2 Merck 1.02382.0500 calcium chloride
CD8+-isolation kit Miltenyi Biotech 130-090-859
D(+)-glukose Merck 1.08337.1000
DMEM Gibco 31966-021 warm in 37 °C water bath before use
EDTA Sigma E5134
FCS PAA Laboratories A15-151 fetal calve serum
gentamicin Gibco 15750-060
HEPES 1M Gibco 15630-050
IL-2 Peprotech 212-12
Isofluran Abbott 05260-05
KCl Merck 1.04933.0500 potassium chloride
KHCO3 Sigma P9144 potassium hydrogen carbonate
L-Glutamine Gibco 35050-038
MgSO4 Merck 1.05886.0500 magnesium sulfate
NaCl Sigma 31434 sodium chloride
NaH2PO4 * H2O Merck 1.06346.0500 sodium hydrogen phosphate
NaHCO3 Merck 1.06329.0500 sodium hydrogen carbonate
NaOH Merck 1.09137.1000 sodium hydroxide
NH4Cl Sigma 213330 ammonium chloride
Non Essential Amino Acid Gibco 11140-050
OVA (257-264) Genscript RP10611 ovalbumin
PIPES Sigma P6757
Sukrose Merck 1.07687.1000
Tissue-Tek OCT Sakura 4583

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Göbel, K., Bittner, S., Cerina, M., Herrmann, A. M., Wiendl, H., Meuth, S. G. An Ex vivo Model of an Oligodendrocyte-directed T-Cell Attack in Acute Brain Slices. J. Vis. Exp. (96), e52205, doi:10.3791/52205 (2015).

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