基于网络药理学和实验验证探讨贯叶金丝桃活性成分调钙抗抑郁作用机制

doi:10.3969/j.issn.1006-5725.2026.10.018

摘要/Abstract

摘要：

目的基于网络药理学数据挖掘和实验验证探讨贯叶金丝桃（Hypericum perforatum L.）主要活性成分抗抑郁作用机制。方法通过文献检索和中药系统药理学数据库与分析平台等方法获取贯叶金丝桃主要活性成分，利用GeneCards数据库、STRING数据库、DAVID数据库进行网络药理学分析及GO富集分析和KEGG富集通路分析。利用Cytoscape 3.8.2软件构建贯叶金丝桃活性成分－靶点网络，筛选度值≥ 10、介数中心性≥ 0.01的节点进行拓扑分析。同时进行细胞实验和动物实验验证，将小胶质细胞（BV-2）分为正常组（Control）组、脂多糖（LPS）组、金丝桃素（HY）组以及钙调磷酸酶抑制剂（CNIS）组，利用免疫荧光法检测离子钙结合接头分子1（IBA-1）阳性表达和Western blot测定相关蛋白表达量。同时，将C57BL/6J小鼠随机分为Control组、抑郁（DP）组和HY组各15只，利用行为学检测黑白场实验（LDB）、旷场实验（OFT）、悬尾实验（TST）评估金丝桃素对慢性不可预见性应激（CUMS）诱导的DP样行为的改善作用，利用Western blot检测炎症因子肿瘤坏死因子α（TNF-α）和钙离子通路相关蛋白表达水平。结果筛选得到贯叶金丝桃中8个活性成分，预测到80个潜在的与抑郁相关的靶点；通过构建有效成分与交集基因可视化分析图发现HY在抗抑郁中发挥较为主要作用，再根据“成分-通路-靶点网络图”网络图发现在抗抑郁中关键的信号通路为钙离子信号通路。细胞实验结果表示，与Control组相比，LPS组IBA-1表达明显上升（P < 0.05）和促炎细胞因子及钙调蛋白（CaM）－钙调磷酸酶蛋白（CN）-活化T细胞因子（NFAT）钙信号通路的蛋白表达量显著升高（P < 0.05）；而与LPS组相比，HY组的IBA-1表达明显降低（P < 0.05）和TNF-α及CaM-CN-NFAT钙信号通路的蛋白表达显著降低（P < 0.05）。动物实验结果表示，与Control组相比，DP组小鼠OFT中央区域停留时间显著缩短（P < 0.05），LDB明暗箱穿梭次数显著减少（P < 0.05），TST不动时间显著延长（P < 0.05），促炎细胞因子（TNF-α）及钙信号通路的蛋白表达水平显著升高（P < 0.05），HY组逆转了上述结果。结论通过网络药理分析初步揭示了贯叶金丝桃抗抑郁活性成分作用机制并进行了体内外验证，为进一步的药理机制研究提供了理论依据。

关键词: 网络药理学, 贯叶金丝桃, 金丝桃素, 抑郁症, 药理机制

Abstract:

Objective To explore the antidepressant mechanism of the main active ingredients of Hypericum perforatum L. through network pharmacology data mining and experimental validation. Methods The main active ingredients of Hypericum perforatum L. were retrieved from the literature and the Traditional Chinese Medicine Systems Pharmacology Database and Analysis Platform. Network pharmacology analysis， GO enrichment analysis， and KEGG pathway enrichment analysis were carried out using the GeneCards， STRING， and DAVID databases. The active ingredient–target network of Hypericum perforatum was constructed with Cytoscape 3.8.2 software. Nodes with a degree value of at least 10 and betweenness centrality of at least 0.01 were selected for topological analysis. Meanwhile， cellular and animal experiments were conducted to validate the results. Microglial cells （BV-2） were divided into four groups： Control， lipopolysaccharide （LPS）， hypericin （HY）， and calcineurin inhibitor （CNIS）. Immunofluorescence was employed to detect the positive expression of ionized calcium-binding adapter molecule 1 （IBA-1）， and Western blot was utilized to determine the expression levels of related proteins. Additionally， C57BL/6J mice were randomly assigned to three groups： Control， depression （DP）， and HY groups （n = 15 per group）. Behavioral tests， such as the light-dark box （LDB）， open field test （OFT）， and tail suspension test （TST）， were used to assess the ameliorative effect of hypericin on chronic unpredictable mild stress （CUMS）-induced depression-like behaviors. Western blot was also used to measure the expression levels of the inflammatory factor tumor necrosis factor-α （TNF-α） and proteins related to the calcium signaling pathway. Results Eight active ingredients were screened from Hypericum perforatum， and 80 potential depression-related targets were predicted. Through visualization analysis of the active ingredients and intersecting genes， it was found that HY plays a major role in the antidepressant effect. The “ingredient?pathway?target” network analysis indicated that the calcium signaling pathway was a key pathway. Cell experiments demonstrated that， in comparison with the Control group， the LPS group showed a significant increase in IBA-1 expression （P < 0.05） and a significant increase in the protein expression of pro-inflammatory cytokines and the CaM-CN-NFAT calcium signaling pathway （P < 0.05）. In contrast， compared with the LPS group， the HY group presented a significant decrease in IBA-1 expression （P < 0.05） and a significant decrease in the protein expression of TNF-α and the CaM-CN-NFAT calcium signaling pathway （P < 0.05）. Animal experiments revealed that， when compared with the Control group， the DP group had a significant shortening of the central zone time in the OFT （P < 0.05）， a significant reduction in the number of transitions in the LDB （P < 0.05）， a significant prolongation of immobility time in the TST （P < 0.05）， and a significant increase in the protein expression of TNF-α and calcium signaling pathway proteins （P < 0.05）. All these changes were reversed in the HY group. Conclusion This study has preliminarily revealed the mechanism of antidepressant active ingredients from Hypericum perforatum L. via network pharmacology analysis combined with in vivo and in vitro validation， thus providing a theoretical basis for further pharmacological research.

Key words: network pharmacology, hypericum perforatum, hypericin, depression, pharmacological mechanism

中图分类号:

R285

林萍燕,高正涛,刘海鑫,周炳灿,陈明恒,刘尔祺,雷添翔,林瑶,许茜. 基于网络药理学和实验验证探讨贯叶金丝桃活性成分调钙抗抑郁作用机制[J]. 实用医学杂志, 2026, 42(10): 1828-1839.

Pingyan LIN,Zhengtao GAO,Haixin LIU,Bingcan ZHOU,Mingheng CHEN,Erqi LIU,Tianxiang LEI,Yao LIN,Qian XU. Exploring the mechanism of calcium regulation and antidepressant effect of active components from Hypericum perforatum L. based on network pharmacology and experimental verification[J]. The Journal of Practical Medicine, 2026, 42(10): 1828-1839.

图/表 15

表1

图1

图2

图3

图4

图5

图6

图7

表2

图8

表3

图9

表4

表5

图10

参考文献 26

[1]	盛可心，王昊冉，徐凌川，等. 贯叶连翘药理作用及其机制研究新进展［J］. 中药药理与临床， 2023， 39（3）： 117-122. doi： 10.13412/j.cnki.zyyl.20220601.007 . doi: 10.13412/j.cnki.zyyl.20220601.007
[2]	MERK V M， BOONEN G， BUTTERWECK V. St. John’s wort for depression： From neurotransmitters to membrane plasticity［J］. Int J Mol Sci， 2025， 26（24）： 11925. doi：10.3390/ijms262411925 . doi: 10.3390/ijms262411925
[3]	YOSHITAKE T， IIZUKA R， YOSHITAKE S， et al. Hypericum perforatum L （St John’s wort） preferentially increases extracellular dopamine levels in the rat prefrontal cortex［J］. British J Pharmacology， 2004， 142（3）： 414-418. doi：10.1038/sj.bjp.0705822 .. doi: 10.1038/sj.bjp.0705822
[4]	陈万平. 贯叶连翘中金丝桃素提取纯化工艺及其抗氧化机理研究［D］. 兰州：兰州理工大学， 2023. doi： 10.27206/d.cnki.ggsgu.2023.000958 . doi: 10.27206/d.cnki.ggsgu.2023.000958
[5]	BHATTA Y， MALLA A， CHAURASIYA K A， et al. Fahr's Disease： A Rare Neurological Disorder Associated with Secondary Cause［J］. Kathmandu Univ Med J （KUMJ）， 2023， 21（83）：337-339. doi： 10.47391/JPMA.22-40 . doi: 10.47391/JPMA.22-40
[6]	ZHANG J， LV S， TANG G， et al. Activation of calcium-impermeable GluR2-containing AMPA receptors in the lateral habenula produces antidepressant-like effects in a rodent model of Parkinson’s disease［J］. Exp Neurol， 2019， 322： 113058. doi：10.1016/j.expneurol.2019.113058 . doi: 10.1016/j.expneurol.2019.113058
[7]	MORRIS G， PURI B K， OLIVE L， et al. Endothelial dysfunction in neuroprogressive disorders—causes and suggested treatments［J］. BMC Med， 2020， 18（1）： 305. doi： 10.1186/s12916-020-01749-w . doi: 10.1186/s12916-020-01749-w
[8]	JOLODAR S K， BIGDELI M， MOGHADDAM A H. Hypericin ameliorates maternal separation-induced cognitive deficits and hippocampal inflammation in rats［J］. Mini Rev Med Chem， 2021， 21（9）： 1144-1149. doi： 10.2174/1389557520666200727154453 . doi: 10.2174/1389557520666200727154453
[9]	SĂLCUDEAN A， BODO C R， POPOVICI R A， et al. Neuroinflammation—a crucial factor in the pathophysiology of depression—A comprehensive review［J］. Biomolecules， 2025， 15（4）： 502. doi：10.3390/biom15040502 . doi: 10.3390/biom15040502
[10]	KHOLGHI G， ARJMANDI-RAD S， ZARRINDAST M R， et al. St. Johnʼs wort （Hypericum perforatum） and depression： What happens to the neurotransmitter systems ［J］. Naunyn Schmiedeberg's Arch Pharmacol， 2022， 395（6）： 629-642. doi： 10.1007/s00210-022-02229-z . doi: 10.1007/s00210-022-02229-z
[11]	RIZZO P， ALTSCHMIED L， RAVINDRAN B M， et al. The biochemical and genetic basis for the biosynthesis of bioactive compounds in Hypericum perforatum L.， one of the largest medicinal crops in Europe［J］. Genes， 2020， 11（10）： 1210. doi： 10.3390/genes11101210 . doi: 10.3390/genes11101210
[12]	DONG Y， TAO B， XUE X， et al. Molecular mechanism of Epicedium treatment for depression based on network pharmacology and molecular docking technology［J］. BMC Complementary Med Ther， 2021， 21（1）： 222. doi： 10.1186/s12906-021-03389-w . doi: 10.1186/s12906-021-03389-w
[13]	CHOI B R， JOHNSON K R， MARIC D， et al. Monocyte-derived IL-6 programs microglia to rebuild damaged brain vasculature［J］. Nat Immunol， 2023， 24（7）： 1110-1123. doi： 10.1038/s41590-023-01521-1 . doi: 10.1038/s41590-023-01521-1
[14]	BRÁS J P， BRAVO J， FREITAS J， et al. TNF-alpha-induced microglia activation requires miR-342： Impact on NF-kB signaling and neurotoxicity［J］. Cell Death Dis， 2020， 11： 415. doi：10.1038/s41419-020-2626-6 . doi: 10.1038/s41419-020-2626-6
[15]	WANG J Q， DERGES J D， BODEPUDI A， et al. Roles of non-receptor tyrosine kinases in pathogenesis and treatment of depression［J］. J Integr Neurosci， 2022， 21： 25. doi：10.31083/j.jin2101025 . doi: 10.31083/j.jin2101025
[16]	SABBAH D A， HAJJO R， SWEIDAN K. Review on epidermal growth factor receptor （EGFR） structure， signaling pathways， interactions， and recent updates of EGFR inhibitors［J］. Curr Top Med Chem， 2020， 20（10）： 815-834. doi： 10.2174/1568026620666200303123102 . doi: 10.2174/1568026620666200303123102
[17]	MORENO C， HERMOSILLA T， HARDY P， et al. Cav1.2 activity and downstream signaling pathways in the hippocampus of an animal model of depression［J］. Cells， 2020， 9（12）： 2609. doi：10.3390/cells9122609 . doi: 10.3390/cells9122609
[18]	LI L， YAO M， MENG J， et al. Advances in calcium signalling research for the diagnosis and treatment of depression［J］. Ann Med， 2026， 58（1）： 2620329. doi：10.1080/07853890.2026.2620329 . doi: 10.1080/07853890.2026.2620329
[19]	NORMANN C， FRASE S， HAUG V， et al. Antidepressants rescue stress-induced disruption of synaptic plasticity via serotonin transporter–independent inhibition of L-type calcium channels［J］. Biol Psychiatry， 2018， 84（1）： 55-64. doi：10.1016/j.biopsych.2017.10.008 . doi: 10.1016/j.biopsych.2017.10.008
[20]	FILADI R， DE MARIO A， AUDANO M， et al. Sustained IP3-linked Ca2+ signaling promotes progression of triple negative breast cancer cells by regulating fatty acid metabolism［J］. Front Cell Dev Biol， 2023， 11： 1071037. doi：10.3389/fcell.2023.1071037 . doi: 10.3389/fcell.2023.1071037
[21]	NAJAR M A， REX D A B， MODI P K， et al. A complete map of the Calcium/calmodulin-dependent protein kinase kinase 2 （CAMKK2） signaling pathway［J］. J Cell Commun Signal， 2021， 15（2）： 283-290. doi： 10.1007/s12079-020-00592-1 . doi: 10.1007/s12079-020-00592-1
[22]	FUSE H， ZHENG Y， ALZOUBI I， et al. TAMing gliomas： Unraveling the roles of Iba1 and CD163 in glioblastoma［J］. Cancers， 2025， 17（9）： 1457. doi： 10.3390/cancers17091457 . doi: 10.3390/cancers17091457
[23]	LI T， WANG C. Hypericin alleviates cerebral ischemia/reperfusion injury by modulating endoplasmic reticulum stress［J］. Front Pharmacol， 2026， 16： 1723495. doi：10.3389/fphar.2025.1723495 . doi: 10.3389/fphar.2025.1723495
[24]	WU J J， ZHANG J， XIA C Y， et al. Hypericin： A natural anthraquinone as promising therapeutic agent［J］. Phytomedicine， 2023， 111： 154654. doi： 10.1016/j.phymed.2023.154654 . doi: 10.1016/j.phymed.2023.154654
[25]	LEI C， LI N， CHEN J， et al. Hypericin ameliorates depression-like behaviors via neurotrophin signaling pathway mediating m6A epitranscriptome modification［J］. Molecules， 2023， 28（9）： 3859. doi： 10.3390/molecules28093859 . doi: 10.3390/molecules28093859
[26]	BEUREL E， TOUPS M， NEMEROFF C B. The bidirectional relationship of depression and inflammation： Double trouble［J］. Neuron， 2020， 107（2）： 234-256. doi： 10.1016/j.neuron.2020.06.002 . doi: 10.1016/j.neuron.2020.06.002

类型	活性成分	英文	有效成分命名
黄酮类物质	金丝桃苷	hyperoside	G1
	芦丁	rutin	G2
	槲皮素	quercetin	G3
	槲皮苷	quercitrin	G4
	异槲皮苷	isoquercitrin	G5
间苯三酚衍生物	贯叶金丝桃素	hyperforin	G6
间苯三酚衍生物	加贯叶金丝桃素	adhyperforin	G7
萘骈二蒽酮类	金丝桃素	hypericin，HY	G8

项目	Control组	LPS组	HY组	CNIS组	F值	P值
TNF-α	0.51 ± 0.15	2.73 ± 0.08^***	1.76 ± 0.12^###	2.12 ± 0.12^#	78.30	< 0.001
CaM	0.79 ± 0.02	1.70 ± 0.13^***	0.90 ± 0.02^###	1.38 ± 0.08	28.84	< 0.001
CN	1.61 ± 0.14	3.25 ± 0.11^***	1.97 ± 0.07^###	2.55 ± 0.15^#	32.91	< 0.001
NFAT1	2.24 ± 0.14	3.89 ± 0.14^***	2.61 ± 0.10^###	3.52 ± 0.17	29.55	< 0.001
NFAT4	1.94 ± 0.07	3.66 ± 0.08^***	2.41 ± 0.10^###	2.54 ± 0.12^###	56.00	< 0.001

项目	Control组	DP组	HY组	F值	P值
黑白场实验/次	18.33 ± 0.83	7.79 ± 0.80^***	11.56 ± 0.56^#	52.46	< 0.001
旷场实验/s	14.38 ± 0.68	6.50 ± 0.50^***	10.00 ± 0.53^##	46.81	< 0.001
悬尾实验/s	130.40 ± 3.01	181.40 ± 4.40^***	152.30 ± 1.99^###	60.63	< 0.001

项目	Control组	DP组	HY组	F值	P值
TNF-α	2.28 ± 0.01	3.37 ± 0.09^***	2.77 ± 0.07^##	61.48	< 0.001
CaM	2.29 ± 0.10	4.30 ± 0.41^**	2.58 ± 0.18^##	16.97	0.003
CN	2.03 ± 0.08	3.36 ± 0.07^***	2.80 ± 0.11^##	57.53	< 0.001
NFAT1	2.18 ± 0.17	3.37 ± 0.39	2.52 ± 0.26	4.45	0.065
NFAT4	1.46 ± 0.06	2.55 ± 0.07^***	1.81 ± 0.07^###	61.14	< 0.001