中国组织工程研究

中国组织工程研究 ›› 2026, Vol. 30 ›› Issue (31): 8154-8164.doi: 10.12307/2026.372

• 干细胞培养与分化 stem cell culture and differentiation • 上一篇    下一篇

芍药苷干预炎性因子及异常自噬改善硼替佐米相关周围神经病变

付佳琪1,李  茜2,孙润洁3,夏梦婷1,崔  兴3   

  1. 1山东中医药大学第一临床医学院,山东省济南市   250013;山东中医药大学第二附属医院,2护理部,3肿瘤中心,山东省济南市   250001
  • 收稿日期:2025-06-06 接受日期:2025-09-07 出版日期:2026-11-08 发布日期:2026-05-23
  • 通讯作者: 崔兴,医学博士,主任医师,教授,博士生导师,山东中医药大学第二附属医院肿瘤中心,山东省济南市 250001
  • 作者简介:付佳琪,女,1999年生,山东省聊城市人,汉族,在读硕士,主要从事中西医结合治疗血液病的研究。
  • 基金资助:
    国家自然科学基金面上项目(82274491,82074348),项目负责人:崔兴;山东省自然科学基金创新发展联合基金项目(ZR2023LZL009),项目负责人:崔兴;济南市科技计划项目(202328072,202225014),项目负责人:崔兴

Paeoniflorin intervenes in inflammatory factors and abnormal autophagy to improve bortezomib-induced peripheral neuropathy

Fu Jiaqi1, Li Qian2, Sun Runjie3, Xia Mengting1, Cui Xing3   

  1. 1First Clinical Medical College of Shandong University of Traditional Chinese Medicine, Jinan 250013, Shandong Province, China; 2Department of Nursing, 3Center of Oncology, the Second Affiliated Hospital of Shandong University of Traditional Chinese Medicine, Jinan 250001, Shandong Province, China
  • Received:2025-06-06 Accepted:2025-09-07 Online:2026-11-08 Published:2026-05-23
  • Contact: Cui Xing, MD, Professor, Chief physician, Doctoral supervisor, Center of Oncology, the Second Affiliated Hospital of Shandong University of Traditional Chinese Medicine, Jinan 250001, Shandong Province, China
  • About author:Fu Jiaqi, MS candidate, First Clinical Medical College of Shandong University of Traditional Chinese Medicine, Jinan 250013, Shandong Province, China
  • Supported by:
    the Natural Science Foundation of China (General Program), Nos. 82274491 and 82074348 (both to CX); Shandong Natural Science Foundation Innovation and Development Joint Fund, No. ZR2023LZL009 (to CX); Jinan Municipal Science and Technology Innovation Project, Nos. 202328072 and 202225014 (both to CX)

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摘要:

文题释义:

硼替佐米相关周围神经病变:为硼替佐米最常见的毒副作用之一,主要临床表现有麻木、疼痛、感觉异常、四肢温度感觉改变等,发病机制尚未完全阐明,与蛋白质聚集体的形成、炎症反应、神经营养因子调节异常等相关。目前尚无特效预防和治疗周围神经病变的方法,临床主要通过调整药物剂量、给药时间及方式降低发生率及严重程度,以及应用神经保护剂、止痛药物来对症处理。
芍药苷:是从芍药(如白芍、赤芍)根部提取的主要活性成分,属于单萜苷类化合物,具有抗炎、镇痛、免疫调节、神经保护和抗氧化等多种药理作用,在心血管疾病、神经退行性疾病和自身免疫病中显示出潜在治疗价值。

摘要
背景:研究证实,芍药苷能够通过降低白细胞介素6水平、促进Beclin1表达改善炎症性疾病及神经退行性疾病中的自噬缺陷,但关于芍药苷对硼替佐米相关周围神经病变的改善作用及机制尚未阐明。
目的:探讨芍药苷干预炎性因子及异常自噬改善硼替佐米相关周围神经病变的作用及分子机制。
方法:①网络药理学分析:应用PubChem数据库获取芍药苷2D结构文件,上传至Swiss Target Prediction数据库预测靶点,在GeneCards、OMIM数据库检索硼替佐米相关周围神经病变的疾病靶点基因,将获得的芍药苷作用靶点与硼替佐米相关周围神经病变的疾病靶点取交集,即为芍药苷干预硼替佐米相关周围神经病变的作用靶点,将获得的交集靶点进行GO和KEGG通路富集分析,构建“靶点-通路”网络,根据靶点蛋白互作网络及“靶点-通路”网络节点度值选取芍药苷关键作用靶点,对芍药苷与核心靶点进行分子对接。②细胞实验:取对数生长期的大鼠肾上腺嗜铬细胞瘤细胞PC12(或人骨髓瘤细胞株MM.1S),分3组培养:对照组不加入任何药物,模型组加入硼替佐米,芍药苷组同时加入芍药苷与硼替佐米。培养48 h后,CCK-8法检测PC12细胞(或MM.1S细胞)活性,ELISA法检测PC12细胞内白细胞介素6水平,免疫荧光检测PC12细胞中LC3B表达,Western blot检测PC12细胞中LC3Ⅰ、LC3Ⅱ、Beclin1蛋白表达,透射电镜观察PC12细胞自噬水平。③动物实验:将45只C57BL/6J小鼠随机分为3组:对照组(n=15)不进行任何干预,模型组(n=15)通过腹腔注射硼替佐米建立硼替佐米相关周围神经病变模型,芍药苷组(n=15)在硼替佐米相关周围神经病变模型过程中给予芍药苷灌胃,1次/d,连续给药25 d。给药结束后,检测小鼠热痛觉敏感性、血清白细胞介素6水平、坐骨神经组织形态与LC3Ⅰ、 LC3Ⅱ、Beclin1表达。
结果与结论:①网络药理学分析:共获得芍药苷干预硼替佐米相关周围神经病变的16个潜在治疗靶点,网络拓扑分析显示白细胞介素6、Beclin1是其中的重要靶点,并且芍药苷与二者均具有良好的结合力。②细胞实验:硼替佐米导致PC12细胞活性显著下降,并伴随着白细胞介素6水平升高与自噬水平的降低,而芍药苷可以减少白细胞介素6分泌、促进自噬,改善PC12细胞活性,并且不影响硼替佐米对骨髓瘤细胞的药效。③动物实验:硼替佐米应用后小鼠热痛觉敏感性增加、血清白细胞介素6水平升高、坐骨神经组织损伤以及坐骨神经内自噬水平降低,芍药苷能够显著改善小鼠的热痛觉敏感性、减轻坐骨神经损伤、降低血清白细胞介素6表达、纠正硼替佐米所致的自噬抑制。④结果表明:芍药苷能够通过抑制白细胞介素6分泌并恢复神经细胞自噬功能改善硼替佐米相关周围神经病变,并且不会影响硼替佐米对多发性骨髓瘤的疗效。

关键词: 芍药苷, 硼替佐米, 周围神经病变, 自噬, 白细胞介素6, 多发性骨髓瘤, PC12细胞

Abstract: BACKGROUND: Studies have shown that paeoniflorin can improve autophagy defects in inflammatory and neurodegenerative diseases by reducing interleukin-6 levels and promoting Beclin1 expression. However, the effect and mechanism by which paeoniflorin improves bortezomib-induced peripheral neuropathy remain unclear.
OBJECTIVE: To explore the effect and molecular mechanism of paeoniflorin on inflammatory factors and abnormal autophagy to improve bortezomib-induced peripheral neuropathy.
METHODS: (1) Network pharmacology analysis: The two-dimensional structure of paeoniflorin was retrieved from the PubChem database and uploaded to the Swiss Target Prediction database for target prediction. Disease-associated targets of bortezomib-induced peripheral neuropathy were identified using the GeneCards and OMIM databases. The intersection between paeoniflorin’s predicted targets and genes related to bortezomib-induced peripheral neuropathy was defined as potential therapeutic targets for paeoniflorin intervention. Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analyses were performed on these intersection targets. A “target-pathway” network was constructed, and key paeoniflorin targets were selected based on node degree values from both protein-protein interaction and “target-pathway” networks. Molecular docking was then conducted to validate the binding interactions between paeoniflorin and its potential targets. (2) Cell experiments: Rat pheochromocytoma cells PC12 (or human myeloma cell line MM.1S) in logarithmic growth phase were cultured in three groups: the control group was not treated with any drugs, the model group was treated with bortezomib, and the paeoniflorin group was treated with both paeoniflorin and bortezomib. After 48 hours of culture, the cell counting kit-8 was used to detect the activity of PC12 cells (or MM.1S cells), ELISA was used to detect the level of interleukin-6 in PC12 cells, immunofluorescence was used to detect the expression of LC3B in PC12 cells, western blot was used to detect the expression of LC3 I, LC3 II, and Beclin1 proteins in PC12 cells, and transmission electron microscopy was used to observe the level of autophagy in PC12 cells. (3) Animal experiment: 45 C57BL/6J mice were randomly divided into three groups: the control group (n=15) did not receive any intervention, the model group (n=15) established a bortezomib-induced peripheral neuropathy model by intraperitoneal injection of bortezomib, and the paeoniflorin group (n=15) was given paeoniflorin orally once a day for 25 consecutive days during the bortezomib-induced peripheral neuropathy model process. After administration, the thermal pain sensitivity, serum interleukin-6 levels, sciatic nerve tissue morphology, and LC3 I, LC3 II, Beclin1 expression in mice were detected.
RESULTS AND CONCLUSION: (1) Network pharmacology analysis identified 16 potential therapeutic targets of paeoniflorin for bortezomib-induced peripheral neuropathy. Network topology analysis revealed interleukin-6  and Beclin-1 as key targets, with paeoniflorin demonstrating strong binding affinity to both proteins. (2) Results from the cell experiment demonstrated that bortezomib significantly reduced viability of PC12 cells while increasing interleukin-6 levels and decreasing autophagy activity. Paeoniflorin treatment effectively reduced interleukin-6 secretion, enhanced autophagy, and improved PC12 cell viability without compromising the anti-myeloma efficacy of bortezomib. (3) Animal experiments showed that bortezomib administration significantly increased thermal pain sensitivity, elevated serum interleukin-6 levels, aggravated sciatic nerve damage, and reduced autophagy levels within the sciatic nerve , whereas paeoniflorin treatment significantly improved thermal pain sensitivity, alleviated sciatic nerve injury, reduced serum interleukin-6 expression, and ameliorated bortezomib-induced autophagy defects in mice. (4) To conclude, paeoniflorin mitigates bortezomib-induced peripheral neuropathy by suppressing interleukin-6 and restoring neuronal autophagy, without compromising bortezomib’s anti-myeloma efficacy.

Key words: paeoniflorin, bortezomib, peripheral neuropathy, autophagy, interleukin-6, multiple myeloma, PC12 cells

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