纵向暴露于抗癫痫药物会影响肠道微生物组、抗性组和代谢组景观。

IF 5.1 Q1 ECOLOGY ISME communications Pub Date : 2024-10-18 eCollection Date: 2024-01-01 DOI:10.1093/ismeco/ycae123
Camille Dop, Stéphane Auvin, Stanislas Mondot, Patricia Lepage, Zehra Esra Ilhan
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引用次数: 0

摘要

与抗生素相比,人们对长期服用的宿主靶向药物对肠道微生物组的影响了解仍然较少。我们利用从幼儿粪便中构建的微生态系统,研究了三种常见抗癫痫药物[卡马西平(CBZ)、丙戊酸和左乙拉西坦]的重复暴露对肠道微生物组成、抗性组和代谢组的影响。微生态系统是通过将粪便培养 24 小时(C0)而建立的。每天将这些微生态系统转移到新鲜培养基中,进行七个周期(C1-C7)的抗癫痫药物或载体分子培养,然后进行四个周期(C8-C11)的不含任何药物的培养。分别通过 16S 核糖体核糖核酸基因测序或枪式元基因组测序以及抗菌素耐药基因的实时定量聚合酶链反应分析,评估了 C0、C1、C7 和 C11 微生物群的微生物动态和耐药基因组。使用非靶向代谢组学方法对 CBZ 处理过的微生态系统和对照微生态系统在 C0、C1 和 C7 的代谢物进行了评估。我们的研究结果表明,序列转移方法纵向改变了微生态圈的组成。在各种药物中,CBZ 对粪便衍生微生态系统的结构和代谢影响最大。在无药期间,微生物组的组成得到了部分恢复。具体来说,乳酸杆菌和黄杆菌减少,而埃希氏菌和梭状芽孢杆菌增加。此外,重复暴露于 CBZ 会增加与各种抗生素耐药机制有关的基因的丰度和表达,特别是外排泵和抗生素靶点改变。CBZ诱导的微生物组变化反映在代谢组中,柠檬酸循环代谢物、谷氨酰胺和亚精胺减少,维生素B6水平升高。我们的研究表明,反复接触 CBZ 可能会对肠道微生物的平衡和代谢产生负面影响。
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Longitudinal exposure to antiseizure medications shape gut-derived microbiome, resistome, and metabolome landscape.

The influence of chronically administered host-targeted drugs on the gut microbiome remains less understood compared to antibiotics. We investigated repetitive exposure effects of three common antiseizure medications [carbamazepine (CBZ), valproic acid, and levetiracetam] on the gut microbial composition, resistome, and metabolome using microcosms constructed from feces of young children. Microcosms were established by cultivating feces for 24 h (C0). These microcosms were daily transferred into fresh media for seven cycles (C1-C7) with antiseizure medications or carrier molecules, followed by four cycles without any drugs (C8-C11). The microbial dynamics and resistome of microcosms at C0, C1, C7, and C11 were assessed with 16S ribosomal ribonucleic acid gene sequencing or shotgun metagenome sequencing and real-time quantitative polymerase chain reaction analysis of the antimicrobial resistance genes, respectively. Metabolites of CBZ-treated and control microcosms at C0, C1, and C7 were evaluated using non-targeted metabolomics. Our findings revealed that the serial transfer approach longitudinally altered the microcosm composition. Among the medications, CBZ had the most substantial impact on the structure and metabolism of the feces-derived microcosms. The microbiome composition partially recovered during the drug-free period. Specifically, Bacteroides and Flavonifractor were depleted and Escherichia and Clostridium were enriched. Additionally, repetitive CBZ exposure increased the abundance and expression of genes related to various antibiotic resistance mechanisms, more specifically, efflux pumps and antibiotic target alteration. CBZ-induced changes in the microbiome were mirrored in the metabolome, with reductions in the citric acid cycle metabolites, glutamine, and spermidine, alongside increased levels of vitamin B6. Our study suggests that repetitive CBZ exposure may negatively impact gut microbial homeostasis and metabolism.

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