Univ. Lille, INSERM, CHU Lille, U1286 - Infinite - Institute for Translational Research in Inflammation, Lille, France.
Univ. Lille, CHU Lille, Institut Pasteur de Lille, ULR 4483-IMPECS-IMPact de l'Environnement Chimique sur la Santé humaine, Lille, France.
FASEB J. 2020 Sep;34(9):12615-12633. doi: 10.1096/fj.202000562RR. Epub 2020 Jul 30.
Although it is known that zinc has several beneficial roles in the context of gut inflammation, the underlying mechanisms have not been extensively characterized. Zinc (Zn) is known to be the primary physiological inducer of the expression of the metallothionein (MT) superfamily of small stress-responsive proteins. The expression of MTs in various tissues is induced or enhanced (including the gastrointestinal tract (GIT)) by a variety of stimuli, including infection and inflammation. However, the MTs' exact role in inflammation is still subject to debate. In order to establish whether or not MTs are the sole vectors in the Zn-based modulation of intestinal inflammation, we used transcriptomic and metagenomic approaches to assess the potential effect of dietary Zn, the mechanisms underlying the MTs' beneficial effects, and the induction of previously unidentified mediators. We found that the expression of endogenous MTs in the mouse GIT was stimulated by an optimized dietary supplementation with Zn. The protective effects of dietary supplementation with Zn were then evaluated in mouse models of chemically induced colitis. The potential contribution of MTs and other pathways was explored via transcriptomic analyses of the ileum and colon in Zn-treated mice. The microbiota's role was also assessed via fecal 16S rRNA sequencing. We found that high-dose dietary supplementation with Zn induced the expression of MT-encoding genes in the colon of healthy mice. We next demonstrated that the Zn diet significantly protected mice in the two models of induced colitis. When comparing Zn-treated and control mice, various genes were found to be differentially expressed in the colon and the ileum. Finally, we found that Zn supplementation did not modify the overall structure of the fecal microbiota, with the exception of (i) a significant increase in endogenous Clostridiaceae, and (ii) some subtle but specific changes at the family and genus levels. Our results emphasize the beneficial effects of excess dietary Zn on the prevention of colitis and inflammatory events in mouse models. The main underlying mechanisms were driven by the multifaceted roles of MTs and the other potential molecular mediators highlighted by our transcriptomic analyses although we cannot rule out contributions by other factors from the host and/or the microbiota.
虽然已知锌在肠道炎症方面具有多种有益作用,但尚未广泛阐明其潜在机制。锌(Zn)是诱导金属硫蛋白(MT)家族小分子应激反应蛋白表达的主要生理性诱导物。各种刺激物(包括感染和炎症)会诱导或增强包括胃肠道(GIT)在内的各种组织中 MT 的表达。然而,MT 在炎症中的确切作用仍存在争议。为了确定 MT 是否是 Zn 调节肠道炎症的唯一载体,我们使用转录组学和宏基因组学方法来评估膳食 Zn 的潜在影响、MT 有益作用的潜在机制以及以前未识别的介质的诱导。我们发现,通过优化膳食 Zn 补充,可刺激小鼠 GIT 中内源性 MT 的表达。然后在化学诱导结肠炎的小鼠模型中评估了 Zn 膳食补充的保护作用。通过对 Zn 处理小鼠的回肠和结肠进行转录组分析,探讨了 MT 和其他途径的潜在贡献。还通过粪便 16S rRNA 测序评估了微生物群的作用。我们发现,高剂量膳食 Zn 补充可诱导健康小鼠结肠 MT 编码基因的表达。接下来,我们证明 Zn 饮食可显著保护两种诱导结肠炎模型中的小鼠。与对照小鼠相比,在结肠和回肠中发现了各种差异表达的基因。最后,我们发现 Zn 补充不会改变粪便微生物群的整体结构,除了(i)内源性梭菌科的显著增加,以及(ii)在科和属水平上的一些细微但特定的变化。我们的研究结果强调了过量膳食 Zn 对预防结肠炎和炎症事件的有益作用。主要的潜在机制是由 MT 的多方面作用以及我们的转录组学分析所强调的其他潜在分子介质驱动的,尽管我们不能排除宿主和/或微生物群的其他因素的贡献。
