To investigate the effects of artemisinin on inflammatory factors and intestinal microbiota in rats with ulcerative colitis based on network pharmacology

Yuxi Guo, Zexie Li, N. Cheng, X. Jia, Jie Wang, Hongyu Ma, Runyuan Zhao, Bolin Li, Yanru Cai, Qian Yang
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Abstract

Objective To investigate the therapeutic effect and possible mechanism of artemisinin on ulcerative colitis (UC) induced by sodium glucan sulfate (DSS) in rats based on network pharmacology. Methods First, according to the 3D structure of artemisinin, the effective targets of the active compounds were obtained through the Swissstarge website (www.swisstargetprediction.ch/) and the TargetNet website (http://targetnet.scbdd.com/). With the aid of Genecards (https://www.genecards.org/), OMIM (https://omim.org/), TTD (http://db.idrblab.net/ttd/) to obtain effective targets of disease. The disease gene-drug target network was constructed by extracting the intersection targets of the two, and the visualization operation and analysis were performed by using Cytoscape 3.7.2. Gene function enrichment analysis and pathway analysis were performed on the intersection targets with the help of R language software. Autidock Vina was used for molecular docking of artemisinin to key targets. Then, 40 male Wistar rats were randomly divided into normal group, model group, mesalazine group (0.315 g/kg·d) and artemisinin group (0.1 g/kg·d), with 10 rats in each group. Except for the normal group, the rats in the other groups were given 3.5% DSS solution freely for 10 days to replicate the UC model. After the successful modeling, the rats were given intragastric administration. The normal group and the model group were given the same amount of 0.9% normal saline, once a day, for 14 days. The general condition of the rats was recorded every day and the disease activity index (DAI) score was performed. After the administration, the colonic mucosal damage index (CMDI) was scored, the histopathological changes of the colon were observed by HE staining, and the levels or activities of serum CRP, TNF-α, MDA, SOD, HIF-1α and T-AOC were detected by ELISA, and fecal and intestinal microbiota of rats were detected by 16S rDNA sequencing. Results Network pharmacology shows that, there were 98 key targets of artemisinin screening, 4853 effective targets of UC, and 43 intersection targets for artemisinin and UC, involving 48 signaling pathways. The molecular docking results showed that the binding energies of the key proteins to artemisinin were less than -5.0 kJ·mol-1, and the binding energy of PTGS2 NOS3 to artemisinin was the best. Animal experiments have shown that, Compared with the model group, the DAI and CMDI scores of the artemisinin group and the mesalazine group decreased, the levels and activities of serum CRP, TNF-α, MDA and HIF-1α decreased, the levels and activities of SOD and T-AOC increased, the abundance and diversity of inteatinal microbiota increased, and the abundance of p-Acidobacteria, p-Chloroflexi, p-Gemmatimonadetes, p-Nitrospirae in artemisinin group increased (P<0.05), and there was no significant change in others. Conclusion Artemisinin intervenes with UC through key target proteins such as PTGS2 and ESR1, and involves various biological processes such as inflammation and intestinal microbiota, revealing that molecular basis of artemisinin in the treatment of UC. Artemisinin is effective in improving the symptoms of UC rats, and its mechanism may be to relieve oxidative stress response by inhibiting inflammation, thus promoting intestinal mucosal repair. The regulatory effect on intestinal microbiota needs to be further studied.
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基于网络药理学研究青蒿素对溃疡性结肠炎大鼠炎症因子和肠道微生物群的影响
目的基于网络药理学研究青蒿素对硫酸葡聚糖钠(DSS)诱导的大鼠溃疡性结肠炎(UC)的治疗作用及其可能机制。方法首先,根据青蒿素的三维结构,通过Swissstarge网站(www.swisstargeteprediction.ch/)和TargetNet网站获得活性化合物的有效靶标(http://targetnet.scbdd.com/)。在基因卡的帮助下(https://www.genecards.org/),OMIM(https://omim.org/),TTD(http://db.idrblab.net/ttd/)以获得有效的疾病靶点。通过提取两者的交叉靶标构建疾病基因药物靶标网络,并使用Cytoscape 3.7.2进行可视化操作和分析。利用R语言软件对交叉靶点进行基因功能富集分析和通路分析。Autidock Vina用于青蒿素与关键靶点的分子对接。然后,将40只雄性Wistar大鼠随机分为正常组、模型组、美沙拉秦组(0.315g/kg·d)和青蒿素组(0.1g/kg·d,每组10只)。除正常组外,其他组大鼠均给予3.5%DSS溶液10天,以复制UC模型。成功建立模型后,对大鼠进行灌胃给药。正常组和模型组给予相同量的0.9%生理盐水,每天一次,持续14天。每天记录大鼠的一般情况,并进行疾病活动指数(DAI)评分。给药后,对结肠粘膜损伤指数(CMDI)进行评分,HE染色观察结肠组织病理学变化,ELISA检测血清CRP、TNF-α、MDA、SOD、HIF-1α和T-AOC水平或活性,16S rDNA测序检测大鼠粪便和肠道微生物群。结果网络药理学显示,青蒿素筛选的关键靶点有98个,UC的有效靶点有4853个,青蒿素与UC的交叉靶点有43个,涉及48条信号通路。分子对接结果表明,关键蛋白与青蒿素的结合能小于-5.0kJ·mol-1,其中PTGS2-NOS3与青蒿素结合能最好。动物实验表明,与模型组相比,青蒿素组和美沙拉秦组的DAI和CMDI评分降低,血清CRP、TNF-α、MDA和HIF-1α水平和活性降低,SOD和T-AOC水平和活性升高,肠道微生物群丰度和多样性增加,青蒿素组对双烯单胺、对硝基螺酰胺含量增加(p<0.05),其他组无明显变化。结论青蒿素通过PTGS2和ESR1等关键靶蛋白干预UC,并涉及炎症和肠道微生物群等多种生物学过程,揭示了青蒿素治疗UC的分子基础。青蒿素能有效改善UC大鼠的症状,其机制可能是通过抑制炎症来缓解氧化应激反应,从而促进肠黏膜修复。对肠道微生物群的调节作用还有待进一步研究。
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