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基因定义的抗性和易感小鼠品系中的流感发病机制

Influenza Pathogenesis in Genetically Defined Resistant and Susceptible Murine Strains

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作者信息

Samet Shelly J, Tompkins Stephen M

机构信息

Center for Vaccines and Immunology, University of Georgia, Athens, GA.

出版信息

Yale J Biol Med. 2017 Sep 25;90(3):471-479. eCollection 2017 Sep.

PMID:28955185
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5612189/
Abstract

The murine infection model is a cornerstone for influenza virus research and includes aspects such as disease pathogenesis, immunobiology, and vaccine and antiviral drug development. One compelling feature of the murine model is the availability of inbred mouse strains, each with a unique genetic makeup and potential for variable responses to influenza infection. Using highly controlled infection studies, the response to influenza virus infection is classified on a spectrum from susceptible to resistant, reflecting severe morbidity and high mortality, to limited or no morbidity and no mortality. Although there have been a variety of studies establishing disparate pathogenesis amongst various murine strains, thus far, there is no consensus regarding the determinants of the outcome of infection. The goal of this review is to explore and discuss the differences in pathogenesis, as well as the innate and adaptive immune responses to influenza infection that have been described in susceptible and resistant mouse strains. Understanding how host genetics influences the response to influenza infection provides valuable insight into the variable responses seen in vaccine or drug efficacy studies, as well as indicates possible mechanisms contributing to increased disease severity in humans infected with influenza virus with no known risk factors.

摘要

小鼠感染模型是流感病毒研究的基石,涵盖疾病发病机制、免疫生物学以及疫苗和抗病毒药物研发等方面。小鼠模型的一个引人注目的特点是有近交系小鼠品系可供使用,每个品系都有独特的基因组成,对流感感染可能有不同的反应。通过高度可控的感染研究,对流感病毒感染的反应可分为从易感到抗性的一系列情况,分别反映出严重发病和高死亡率,到有限发病或无发病以及无死亡。尽管已经有各种研究确定了不同小鼠品系之间不同的发病机制,但到目前为止,关于感染结果的决定因素尚无共识。本综述的目的是探讨和讨论在易感和抗性小鼠品系中所描述的流感感染发病机制差异以及先天和适应性免疫反应。了解宿主基因如何影响对流感感染的反应,可为疫苗或药物疗效研究中观察到的不同反应提供有价值的见解,也有助于揭示在无已知风险因素的流感病毒感染人类中导致疾病严重程度增加的可能机制。

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