毛螺菌科
阿克曼西亚
生物
肠道菌群
缬氨酸
微生物群
代谢组
生物化学
失调
代谢组学
某种肠道细菌
微生物学
普氏粪杆菌
乳酸菌
氨基酸
厚壁菌
生物信息学
基因
发酵
16S核糖体RNA
作者
Pei Han,Lisha Li,Zixi Wang,Lin Xi,Hang Yu,Cong Lin,Zhengwei Zhang,Jie Fu,Ran Peng,Li‐Bin Pan,Shurong Ma,Xueyan Wang,Xueyan Wang,Hongtian Wang,Xiangdong Wang,Xiangdong Wang,Yan Wang,Jinlyu Sun,Jian‐Dong Jiang
出处
期刊:Engineering
[Elsevier BV]
日期:2021-05-01
卷期号:15: 115-125
被引量:5
标识
DOI:10.1016/j.eng.2021.03.013
摘要
Due to the worldwide epidemic of allergic disease and a cure nowhere in sight, there is a crucial need to explore its pathophysiological mechanisms. As allergic disease has been associated with gut dysbiosis, we searched for a possible mechanism from the perspective of the molecular interface between host and microbiota with concurrent metabolomics and microbiome composition analysis. Sprague-Dawley rats were injected with Artemisia pollen extract to stimulate a hyper reaction to pollen. This hyper reaction decreased the circulation of valine, isoleucine, aspartate, glutamate, glutamine, indole-propionate (IPA), and myo-inositol, and reduced short-chain fatty acids (SCFAs) in feces. Several beneficial genera belonging to Ruminococcaceae, Lachnospiraceae, and Clostridiales declined in the model group, whereas Helicobacter and Akkermansia were only expressed in the model group. Furthermore, the expression of intestinal claudin-3 and liver fatty acid binding protein was downregulated in the model group and associated with metabolic changes and bacteria. Our results suggest that alterations in amino acids as well as their derivatives (especially valine, and IPA which is the reductive product of tryptophan), SCFAs, and the gut microbiome (specifically Akkermansia and Helicobacter) may disrupt the intestinal barrier function by inhibiting the expression of claudin proteins and affecting the mucus layer, which further results in hay fever.
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