Microplastics induce liver inflammation in cattle through the rumen microbiota-gut-liver axis.

IF 12.7 1区生物学 Q1 MICROBIOLOGY

Microbiome Pub Date : 2026-05-05 DOI:10.1186/s40168-026-02399-5

Zhiqing Li, Yu Ge, Xinwei Ma, Shuyu Jiang, Zan Liang, Lei Liu, Yongle Luo, Chunqiu Xia, Hu Liu, Qianglin Liu, Jishan An, Zuo Wang, Xinyi Lan, Anwei Cheng, Weijun Shen, Fachun Wan

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引用次数: 0

Abstract

Background: Microplastics (MP) pollution is widespread in livestock farming environments. Exposure to MP can impair the gastrointestinal barrier, alter the structure and metabolism of the microbiota, and subsequently lead to organ damage. MP not only hinder cattle farming but also enter the food chain, posing a potential risk. Polyethylene (PE), a type of MP commonly detected in ruminant feed, has not yet been studied for its specific effects on cattle. Using calves as an animal model, this study investigates how exposure to MP induces toxicity via the rumen microbiota-gut-liver axis.

Results: Exposure to MP impaired weight gain and liver development in cattle, altered liver tissue pathology, increased blood lipopolysaccharide (LPS) levels, and triggered a systemic inflammatory response, identifying the liver as the primary target organ. Inflammation was closely associated with the dysbiosis of rumen microbiota and metabolites. MP exposure also damages the barrier integrity of the rumen, jejunum, and colon. The underlying mechanism involves MP altering the rumen microbial composition, which in turn triggers metabolic disorders, activates LPS synthesis pathways, and inhibits tight junction protein expression in the jejunum and colon. Although MP do not cause significant architectural damage to muscle tissue, they disrupt lipid homeostasis and nutrient composition, thereby promoting the deposition of pro-inflammatory LPS within muscle tissue. Rumen fluid metabolomics analysis revealed that differential metabolites were mainly enriched in the ATP-binding cassette transporter (ABC) pathway, with 4-fluoro-3-phenoxybenzoic acid and isovalerylglutamic acid being significantly correlated with levels of LPS, IL-6, TNF-α, and IL-1β. Notably, the concurrent increase in TNF-α and LPS in both the bloodstream and liver, alongside altered blood metabolomics, indicates that MP induce hepatic damage by disrupting the rumen microbiota-gut-liver axis. Transcriptomic analysis revealed that liver inflammatory injury was closely associated with NF-κB activation. Further mechanistic analysis supported the central role of the TLR4/MyD88/NF-κB signaling pathway.

Conclusions: MP impair liver function in cattle by disrupting the rumen microbiota-gut-liver axis. This process involves the perturbation of rumen flora and intestinal barriers, triggering LPS translocation into the bloodstream, and ultimately causing liver damage. Video Abstract.

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微塑料通过瘤胃微生物群-肠道-肝脏轴诱导牛肝脏炎症。

背景：微塑料污染在畜牧业环境中普遍存在。暴露于MP可损害胃肠道屏障，改变微生物群的结构和代谢，并随后导致器官损伤。MP不仅会阻碍养牛，还会进入食物链，构成潜在风险。聚乙烯（PE）是反刍动物饲料中常见的一种多聚物，目前尚未研究其对牛的具体影响。本研究以犊牛为动物模型，研究了暴露于MP如何通过瘤胃微生物群-肠-肝轴诱导毒性。结果：暴露于MP会损害牛的体重增加和肝脏发育，改变肝脏组织病理，增加血液脂多糖（LPS）水平，并引发全身炎症反应，将肝脏确定为主要靶器官。炎症与瘤胃微生物群和代谢物的生态失调密切相关。MP暴露也会破坏瘤胃、空肠和结肠屏障的完整性。潜在的机制涉及MP改变瘤胃微生物组成，进而引发代谢紊乱，激活LPS合成途径，抑制空肠和结肠紧密连接蛋白的表达。虽然MP不会对肌肉组织造成明显的结构损伤，但它们会破坏脂质稳态和营养成分，从而促进促炎LPS在肌肉组织内的沉积。瘤胃液代谢组学分析显示，差异代谢物主要富集于atp结合盒转运体（ABC）途径，4-氟-3-苯氧苯甲酸和异戊酰谷氨酸与LPS、IL-6、TNF-α和IL-1β水平显著相关。值得注意的是，血液和肝脏中TNF-α和LPS的同时增加，以及血液代谢组学的改变，表明MP通过破坏瘤胃微生物群-肠-肝轴诱导肝损伤。转录组学分析显示肝脏炎症损伤与NF-κB活化密切相关。进一步的机制分析支持TLR4/MyD88/NF-κB信号通路的核心作用。结论：MP通过破坏瘤胃微生物群-肠-肝轴损害牛肝功能。这一过程包括对瘤胃菌群和肠道屏障的扰动，引发LPS转运进入血液，最终导致肝脏损伤。视频摘要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Microbiome MICROBIOLOGY-

CiteScore

21.90

自引率

2.60%

发文量

198

审稿时长

4 weeks

期刊介绍： Microbiome is a journal that focuses on studies of microbiomes in humans, animals, plants, and the environment. It covers both natural and manipulated microbiomes, such as those in agriculture. The journal is interested in research that uses meta-omics approaches or novel bioinformatics tools and emphasizes the community/host interaction and structure-function relationship within the microbiome. Studies that go beyond descriptive omics surveys and include experimental or theoretical approaches will be considered for publication. The journal also encourages research that establishes cause and effect relationships and supports proposed microbiome functions. However, studies of individual microbial isolates/species without exploring their impact on the host or the complex microbiome structures and functions will not be considered for publication. Microbiome is indexed in BIOSIS, Current Contents, DOAJ, Embase, MEDLINE, PubMed, PubMed Central, and Science Citations Index Expanded.