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饮食在驾驶座上:野生鱼类中的自然饮食-免疫-微生物组相互作用。

Diet in the Driving Seat: Natural Diet-Immunity-Microbiome Interactions in Wild Fish.

机构信息

School of Environment and Life Sciences, University of Salford, Salford, United Kingdom.

出版信息

Front Immunol. 2019 Feb 19;10:243. doi: 10.3389/fimmu.2019.00243. eCollection 2019.

DOI:10.3389/fimmu.2019.00243
PMID:30837993
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6389695/
Abstract

Natural interactions between the diet, microbiome, and immunity are largely unstudied. Here we employ wild three-spined sticklebacks as a model, combining field observations with complementary experimental manipulations of diet designed to mimic seasonal variation in the wild. We clearly demonstrate that season-specific diets are a powerful causal driver of major systemic immunophenotypic variation. This effect occurred largely independently of the bulk composition of the bacterial microbiome (which was also driven by season and diet) and of host condition, demonstrating neither of these, , constrain immune allocation in healthy individuals. Nonetheless, through observations in multiple anatomical compartments, differentially exposed to the direct effects of food and immunity, we found evidence of immune-driven control of bacterial community composition in mucus layers. This points to the interactive nature of the host-microbiome relationship, and is the first time, to our knowledge, that this causal chain (diet → immunity → microbiome) has been demonstrated in wild vertebrates. Microbiome effects on immunity were not excluded and, importantly, we identified outgrowth of potentially pathogenic bacteria (especially mycolic-acid producing corynebacteria) as a consequence of the more animal-protein-rich summertime diet. This may provide part of the ultimate explanation (and possibly a proximal cue) for the dramatic immune re-adjustments that we saw in response to diet change.

摘要

饮食、微生物组和免疫系统之间的自然相互作用在很大程度上尚未得到研究。在这里,我们以野生三刺鱼为模型,将野外观察与旨在模拟野外季节性变化的饮食补充实验操作相结合。我们清楚地表明,特定季节的饮食是主要系统性免疫表型变异的有力因果驱动因素。这种影响主要独立于细菌微生物组的总体组成(这也受到季节和饮食的驱动)和宿主状况,表明这两者都不会限制健康个体的免疫分配。尽管如此,通过在多个解剖部位进行观察,这些部位直接受到食物和免疫的影响,我们发现了免疫驱动粘液层中细菌群落组成的证据。这表明了宿主-微生物组关系的相互性质,据我们所知,这是在野生脊椎动物中首次证明这种因果链(饮食→免疫→微生物组)。不能排除微生物组对免疫的影响,而且,重要的是,我们发现富含动物蛋白的夏季饮食会导致潜在致病细菌(特别是产生分枝菌酸的棒状杆菌)的过度生长。这可能为我们观察到的对饮食变化的剧烈免疫调整提供了部分最终解释(可能是一个直接的线索)。

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