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18β-甘草次酸通过调控线粒体核糖体蛋白 L35 相关凋亡信号通路抑制胃癌细胞的增殖。

18β-glycyrrhetinic acid regulates mitochondrial ribosomal protein L35-associated apoptosis signaling pathways to inhibit proliferation of gastric carcinoma cells.

机构信息

College of Pharmacy, Ningxia Medical University, Yinchuan 750004, Ningxia Hui Autonomous Region, China.

Traditional Chinese Medicine College, Ningxia Medical University, Yinchuan 750004, Ningxia Hui Autonomous Region, China.

出版信息

World J Gastroenterol. 2022 Jun 14;28(22):2437-2456. doi: 10.3748/wjg.v28.i22.2437.

DOI:10.3748/wjg.v28.i22.2437
PMID:35979263
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9258276/
Abstract

BACKGROUND

Gastric carcinoma (GC) is a common gastrointestinal malignancy worldwide. Based on the cancer-related mortality, the current prevention and treatment strategies for GC still show poor clinical results. Therefore, it is important to find effective drug treatment targets.

AIM

To explore the mechanism by which 18β-glycyrrhetinic acid (18β-GRA) regulates mitochondrial ribosomal protein L35 (MRPL35) related signal proteins to inhibit the proliferation of GC cells.

METHODS

Cell counting kit-8 assay was used to detect the effects of 18β-GRA on the survival rate of human normal gastric mucosal cell line GES-1 and the proliferation of GC cell lines MGC80-3 and BGC-823. The apoptosis and cell cycle were assessed by flow cytometry. Cell invasion and migration were evaluated by Transwell assay, and cell scratch test was used to detect cell migration. Furthermore, a tumor model was established by hypodermic injection of 2.5 × 10 BGC-823 cells at the selected positions of BALB/c nude mice to determine the effect of 18β-GRA on GC cell proliferation, and quantitative reverse transcription-polymerase chain reaction (qRT-PCR) was used to detect expression in the engrafted tumors in mice. We used the term tandem mass tag (TMT) labeling combined with liquid chromatography-tandem mass spectrometry to screen for differentially expressed proteins (DEPs) extracted from GC cells and control cells after 18β-GRA intervention. A detailed bioinformatics analysis of these DEPs was performed, including Gene Ontology annotation and enrichment analysis, Kyoto Encyclopedia of Genes and Genomes pathway enrichment analysis, and so on. Moreover, STRING database (https://string-db.org/) was used to predict protein-protein interaction (PPI) relationships and Western blot was used to detect the expression of proteins of interest in GC cells.

RESULTS

The results indicated that 18β-GRA could inhibit the proliferation of GC cells in a dose- and time-dependent manner. It could induce GC cell apoptosis and arrest the cell cycle at G0/G1 phase. The proportion of cells arrested at S phase decreased with the increase of 18-GRA dose, and the migration and invasiveness of GC cells were inhibited. The results of animal experiments showed that 18β-GRA could inhibit tumor formation in BALB/c nude mice, and qRT-PCR results showed that expression level was significantly reduced in the engrafted tumors in mice. Using TMT technology, 609 DEPs, among which 335 were up-regulated and 274 were down-regulated, were identified in 18β-GRA intervention compared with control. We found that the intervention of 18β-GRA in GC cells involved many important biological processes and signaling pathways, such as cellular processes, biological regulation, and TP53 signaling pathway. Notably, after the drug intervention, MRPL35 expression was significantly down-regulated ( = 0.000247), TP53 expression was up-regulated ( = 0.02676), and BCL2L1 was down-regulated ( = 0.01699). Combined with the Retrieval of Interacting Genes/Proteins database, we analyzed the relationship between MRPL35, TP53, and BCL2L1 signaling proteins, and we found that COPS5, BAX, and BAD proteins can form a PPI network with MRPL35, TP53, and BCL2L1. Western blot analysis confirmed the intervention effect of 18β-GRA on GC cells, MRPL35, TP53, and BCL2L1 showed dose-dependent up/down-regulation, and the expression of COPS5, BAX, and BAD also increased/decreased with the change of 18β-GRA concentration.

CONCLUSION

18β-GRA can inhibit the proliferation of GC cells by regulating MRPL35, COPS5, TP53, BCL2L1, BAX, and BAD.

摘要

背景

胃癌(GC)是一种常见的胃肠道恶性肿瘤。根据癌症相关死亡率,目前 GC 的预防和治疗策略仍然显示出较差的临床效果。因此,寻找有效的药物治疗靶点非常重要。

目的

探讨 18β-甘草次酸(18β-GRA)调节线粒体核糖体蛋白 L35(MRPL35)相关信号蛋白抑制 GC 细胞增殖的机制。

方法

用细胞计数试剂盒-8 检测 18β-GRA 对人正常胃黏膜细胞系 GES-1 存活率和 GC 细胞系 MGC80-3 和 BGC-823 增殖的影响。通过流式细胞术评估细胞凋亡和细胞周期。通过 Transwell 测定评估细胞侵袭和迁移,通过细胞划痕试验检测细胞迁移。此外,通过皮下注射 2.5×10 BGC-823 细胞在 BALB/c 裸鼠选定部位建立肿瘤模型,以确定 18β-GRA 对 GC 细胞增殖的影响,并通过定量逆转录-聚合酶链反应(qRT-PCR)检测小鼠移植瘤中 的表达。我们使用串联质量标签(TMT)标记与液相色谱-串联质谱联用技术筛选 18β-GRA 干预后 GC 细胞和对照细胞中的差异表达蛋白(DEPs)。对这些 DEPs 进行了详细的生物信息学分析,包括基因本体论注释和富集分析、京都基因和基因组百科全书通路富集分析等。此外,使用 STRING 数据库(https://string-db.org/)预测蛋白质-蛋白质相互作用(PPI)关系,并通过 Western blot 检测 GC 细胞中感兴趣的蛋白质的表达。

结果

结果表明,18β-GRA 可呈剂量和时间依赖性地抑制 GC 细胞增殖。它可以诱导 GC 细胞凋亡并将细胞周期阻滞在 G0/G1 期。随着 18-GRA 剂量的增加,S 期细胞的比例减少,GC 细胞的迁移和侵袭能力受到抑制。动物实验结果表明,18β-GRA 可抑制 BALB/c 裸鼠肿瘤的形成,qRT-PCR 结果显示小鼠移植瘤中 的表达水平显著降低。使用 TMT 技术,在 18β-GRA 干预与对照组相比,共鉴定出 609 个 DEPs,其中 335 个上调,274 个下调。我们发现,18β-GRA 干预 GC 细胞涉及许多重要的生物学过程和信号通路,如细胞过程、生物调节和 TP53 信号通路。值得注意的是,药物干预后,MRPL35 表达明显下调( = 0.000247),TP53 表达上调( = 0.02676),BCL2L1 下调( = 0.01699)。结合检索互作基因/蛋白数据库,我们分析了 MRPL35、TP53 和 BCL2L1 信号蛋白之间的关系,发现 COPS5、BAX 和 BAD 蛋白可以与 MRPL35、TP53 和 BCL2L1 形成 PPI 网络。Western blot 分析证实了 18β-GRA 对 GC 细胞的干预作用,MRPL35、TP53 和 BCL2L1 表现出剂量依赖性的上调/下调,随着 18β-GRA 浓度的变化,COPS5、BAX 和 BAD 的表达也增加/减少。

结论

18β-GRA 可以通过调节 MRPL35、COPS5、TP53、BCL2L1、BAX 和 BAD 来抑制 GC 细胞的增殖。

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