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在早期的“机会之窗”中,通过改变肠道微生物群和宿主免疫来定制实验小鼠。

Customizing laboratory mice by modifying gut microbiota and host immunity in an early "window of opportunity".

机构信息

Department of Veterinary Disease Biology, Faculty of Health and Medical Sciences, University of Copenhagen, Frederiksberg, Denmark.

出版信息

Gut Microbes. 2013 May-Jun;4(3):241-5. doi: 10.4161/gmic.23999. Epub 2013 Apr 2.

DOI:10.4161/gmic.23999
PMID:23549457
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3669170/
Abstract

We recently investigated how post-natal microbial gut colonization is important for the development of the immune system, especially in the systemic compartments. This addendum presents additional data which in accordance with our previous findings show that early life microbial colonization is critical for a fine-tuned immune homeostasis to develop also in the intestinal environment. A generalized reduction in the expression of immune signaling related genes in the small intestine may explain previously shown increased systemic adaptive immune reactivity, if the regulatory cross-talk between intra- and extra-intestinal immune cells is immature following a neonatal germ-free period. These findings are furthermore discussed in the context of recently published results on how lack of microbial exposure in the neonatal life modifies disease expression in rodents used as models mimicking human inflammatory diseases. In particular, with a focus on how these interesting findings could be used to optimize the use of rodent models.

摘要

我们最近研究了产后微生物肠道定植对免疫系统发育的重要性,特别是在全身隔室中。本增刊提供了其他数据,这些数据与我们之前的发现一致,表明早期的微生物定植对于在肠道环境中也发展精细的免疫稳态至关重要。如果新生儿无菌期后肠内和肠外免疫细胞之间的调节交叉对话不成熟,那么小肠中与免疫信号相关基因的表达普遍减少可能解释了先前显示的全身适应性免疫反应性增加。这些发现还在讨论中,内容涉及最近发表的关于新生儿期缺乏微生物暴露如何改变用于模拟人类炎症性疾病的模型啮齿动物中疾病表达的结果。特别是,重点介绍了如何利用这些有趣的发现来优化啮齿动物模型的使用。

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