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Fas配体和穿孔素的缺失可保护小鼠免受黄病毒介导的脑炎。

Lack of both Fas ligand and perforin protects from flavivirus-mediated encephalitis in mice.

作者信息

Licon Luna Rosa M, Lee Eva, Müllbacher Arno, Blanden Robert V, Langman Rod, Lobigs Mario

机构信息

Division of Immunology and Cell Biology, John Curtin School of Medical Research, The Australian National University, Canberra, Australian Capital Territory 2601, Australia.

出版信息

J Virol. 2002 Apr;76(7):3202-11. doi: 10.1128/jvi.76.7.3202-3211.2002.

DOI:10.1128/jvi.76.7.3202-3211.2002
PMID:11884544
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC136025/
Abstract

The mechanism by which encephalitic flaviviruses enter the brain to inflict a life-threatening encephalomyelitis in a small percentage of infected individuals is obscure. We investigated this issue in a mouse model for flavivirus encephalitis in which the virus was administered to 6-week-old animals by the intravenous route, analogous to the portal of entry in natural infections, using a virus dose in the range experienced following the bite of an infectious mosquito. In this model, infection with 0.1 to 10(5) PFU of virus gave mortality in approximately 50% of animals despite low or undetectable virus growth in extraneural tissues. We show that the cytolytic effector functions play a crucial role in invasion of the encephalitic flavivirus into the brain. Mice deficient in either the granule exocytosis- or Fas-mediated pathway of cytotoxicity showed delayed and reduced mortality. Mice deficient in both cytotoxic effector functions were resistant to a low-dose peripheral infection with the neurotropic virus.

摘要

在一小部分受感染个体中,引起脑炎的黄病毒进入大脑引发危及生命的脑脊髓炎的机制尚不清楚。我们在黄病毒脑炎小鼠模型中研究了这个问题,该模型中,通过静脉途径给6周龄动物接种病毒,类似于自然感染的进入途径,使用的病毒剂量在被感染蚊子叮咬后所经历的范围内。在这个模型中,尽管神经外组织中病毒生长缓慢或检测不到,但接种0.1至10⁵ PFU病毒会导致约50%的动物死亡。我们发现,溶细胞效应功能在脑炎黄病毒侵入大脑中起关键作用。颗粒胞吐或Fas介导的细胞毒性途径缺陷的小鼠死亡率延迟且降低。两种细胞毒性效应功能均缺陷的小鼠对低剂量嗜神经病毒的外周感染具有抗性。

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