灯盏乙素通过调控MMP7与LCN2改善大鼠代谢功能障碍相关脂肪性肝病

doi:10.12122/j.issn.1673-4254.2026.04.19

南方医科大学学报 ›› 2026, Vol. 46 ›› Issue (4): 907-922.doi: 10.12122/j.issn.1673-4254.2026.04.19

• • 上一篇

灯盏乙素通过调控MMP7与LCN2改善大鼠代谢功能障碍相关脂肪性肝病

马扬¹(), 郭龙辉¹(), 王锦帼², 肖文萍¹, 吕运成³(), 范晓明⁴^,⁵()

^1.桂林医科大学，基础医学院，广西桂林 541004
^2.桂林医科大学，公共卫生学院，广西桂林 541004
^3.桂林医科大学，广西糖尿病系统医学重点实验室，广西桂林 541004
^4.桂林医科大学，广西肿瘤免疫与微环境调控重点实验室，广西桂林 541004
^5.桂林医科大学，广西肿瘤免疫与受体靶向药物基础研究重点实验室，广西桂林 541004

收稿日期:2025-09-14 出版日期:2026-04-20 发布日期:2026-04-24
通讯作者: 吕运成,范晓明 E-mail:mayang@stu.glmc.edu.cn;guolonghui@stu.glmu.edu.cn;anthony0723@163.com;fanxiaom1987@glmc.edu.cn
作者简介:马扬，在读硕士研究生，E-mail: mayang@stu.glmc.edu.cn
郭龙辉，在读硕士研究生，E-mail: guolonghui@stu.glmu.edu.cn
第一联系人：马扬、郭龙辉共同为第一作者
基金资助:
广西自然科学基金面上项目(2023JJA141287);广西科技基地和人才专项项目(2020AC20022);桂林医科大学研究生创新项目(GYYK2025002);国家级大学生创新创业训练项目(202410601012)

Scutellarin improves metabolic dysfunction-associated steatotic liver disease in rats by regulating MMP7 and LCN2

Yang MA¹(), Longhui GUO¹(), Jinguo WANG², Wenpin XIAO¹, Yuncheng LV³(), Xiaoming FAN⁴^,⁵()

^1.School of Basic Medicine, Guilin Medical University, Guilin 541004, China
^2.School of Public Health, Guilin Medical University, Guilin 541004, China
^3.Guangxi Key Laboratory of Diabetic Systems Medicine, Guilin Medical University, Guilin 541004, China
^4.Guangxi Key Laboratory of Tumor Immunology and Microenvironmental Regulation, Guilin Medical University, Guilin 541004, China
^5.Guangxi Health Commission Key Laboratory of Tumor Immunology and Receptor-Targeted Drug Basic Research, Guilin Medical University, Guilin 541004, China

Received:2025-09-14 Online:2026-04-20 Published:2026-04-24
Contact: Yuncheng LV, Xiaoming FAN E-mail:mayang@stu.glmc.edu.cn;guolonghui@stu.glmu.edu.cn;anthony0723@163.com;fanxiaom1987@glmc.edu.cn

摘要/Abstract

摘要：

目的通过生物信息学、网络药理学及动物实验，探讨灯盏乙素（Scu）治疗代谢相关脂肪性肝病（MASLD）的靶点及机制。方法从GEO数据库GSE89632鉴定MASLD差异表达基因（DEGs）。利用PharmMapper预测Scu靶点，Cytoscape构建药效团-靶点网络。R语言的clusterProfiler包进行GO和KEGG通路分析。STRING工具构建PPI网络，cytoHubba和MCODE确定关键治疗（KT）基因。进行分子对接及分子动力学模拟验证。将SD大鼠随机分为对照组、模型组、Scu低/中/高剂量（50、100、200 mg·kg^-1·d^-1）组及辛伐他汀（5 mg·kg^-1·d^-1）组（n=10）。12周高脂高糖饮食造模后，给药组连续灌胃8周。结果共鉴定出810个DEGs 和12个PT基因。GO和KEGG分析指向炎症调控、细胞因子应答、纤维化和代谢相关通路。分子对接和动力学模拟验证了MMP7和LCN2为关键靶点。动物实验显示，Scu剂量依赖改善MASLD大鼠胰岛素抵抗、肝功能，脂质及炎症相关因子，以及肝脏病理改变，高剂量Scu效果优于辛伐他汀（P<0.05）。q-PCR及Western blotting检测发现Scu以剂量依赖的方式上调MMP7的表达，下调LCN2的表达（P<0.05）。结论 Scu可能通过调控MMP7和LCN2发挥抗MASLD的作用。

关键词: 灯盏乙素, 代谢相关脂肪性肝病, 生物信息学, 网络药理学

Abstract:

Objective To identify the therapeutic targets and signaling pathways that mediate the therapeutic effect of scutellarin against metabolic dysfunction-associated steatotic liver disease (MASLD). Methods The differentially expressed genes (DEGs) in liver tissues of MASLD patients and healthy individuals were obtained from the GSE89632 dataset. The potential targets of scutellarin were screened using the PharmMapper database, and a drug-target network was constructed using Cytoscape. Functional enrichment analysis was performed using GO and KEGG pathway analysis. The intersection of scutellarin's target genes and the DEGs formed the potential therapeutic (PT) genes. Protein-protein interaction (PPI) networks were constructed using STRING to identify the key therapeutic (KT) genes. Molecular docking and dynamics simulations were used to assess the drug-target relationship. In a rat model of MASLD treated with different doses of scutellarin, the changes in serum biochemical parameters and liver pathology were analyzed. Results A total of 810 DEGs and 12 PT genes were identified, and GO and KEGG analyses suggested their involvement in inflammation regulation, cytokine response, fibrosis, and metabolism. In the rat models of MASLD, treatment with scutellarin significantly improved insulin resistance, liver function, lipid levels, inflammation, and hepatic pathology in a dose-dependent manner, and high-dose scutellarin produced better therapeutic effects than simvastatin. Scutellarin treatment significantly upregulated MMP7 and downregulated LCN2 expression in the mouse livers. Conclusion Scutellarin ameliorates MASLD in rats possibly by modulating hepatic MMP7 and LCN2 expressions.

Key words: scutellarin, metabolic dysfunction-associated steatotic liver disease, bioinformatics analysis, network pharmacology

马扬, 郭龙辉, 王锦帼, 肖文萍, 吕运成, 范晓明. 灯盏乙素通过调控MMP7与LCN2改善大鼠代谢功能障碍相关脂肪性肝病[J]. 南方医科大学学报, 2026, 46(4): 907-922.

Yang MA, Longhui GUO, Jinguo WANG, Wenpin XIAO, Yuncheng LV, Xiaoming FAN. Scutellarin improves metabolic dysfunction-associated steatotic liver disease in rats by regulating MMP7 and LCN2[J]. Journal of Southern Medical University, 2026, 46(4): 907-922.

图/表 16

表1 引物序列

Tab.1 Primer sequence

Gene name	Primer name	Primer sequence
MMP7	MMP7-F	F: CTCTCTGGGTCTGGGTCACT
	MMP7-R	R: AAGGGCGTTTGCTCATTCCA
LCN2	LCN2-F	F: GCTGTCGCTACTGGATCAGA
	LCN2-R	R: TCGCTCCTTCAGTTCATCGG
GAPDH	GAPDH-F	F: GACATGCCGCCTGGAGAAAC
	GAPDH-R	R: AGCCCAGGATGCCCTTTAGT

图1 GSE89632数据集差异基因的火山图和热图

Fig.1 Volcano map and heat map of the differentially expressed genes (DEGs) in the GSE89632 dataset. A: Volcano map of the detected genes. Each point represents a gene. Blue dots represent down-regulated genes, and red dots represent up-regulated genes. The screening criteria for important genes are: |Log2FC|>1 and P.adj<0.05. B: Heat map of DEGs clustering. Blue indicates low expression and red indicates high expression.

图2 Scu的药效团靶网络

Fig.2 Pharmacophore target network of scutellarin. A: Drug-target network. Scutellarin is located at the center of the network. The potential therapeutic gene (PT gene) for treating MASLD is marked yellow. B: Intersecting DEGs obtained from GSE89632 as the target genes of scutellarin are considered to be the PT genes.

图3 GO功能富集分析

Fig.3 GO functional enrichment analysis. The top 5 are cellular components (CC), biological processes (BP), and molecular functions (MF). A: Rich in MASLD-related DEGs. B: Target gene of S-CU. C: Potential therapeutic genes (PT genes). D: Venn diagrams of GO for DEG and scutellarin (cell component). E: Venn diagrams of GO for DEG and scutellarin (biological process). F: Venn diagrams of GO for DEG and scutellarin (molecular function).

图4 KEGG通路富集分析前10名KEGG

Fig.4 Top 10 KEGGs in KEGG pathway enrichment analysis. A: MASLD-related DEGs. B: Target genes of scutellarin. C: Potential therapeutic genes (PT genes). D: Venn diagrams of the KEGG pathways in DEG and scutellarin.

图5 关键治疗基因(KT基因)筛选

Fig.5 Protein-protein interaction diagram of the key therapeutic gene screening. A: PT gene. B: The top 11 key genes calculated by cytoHubba. C: Analysis of the key module genes using MCODE.

表2 Scu与治疗靶点结合能量值

Tab.2 Binding energy value of scutellarin (Scu) to the therapeutic targets

Target	Drug	Binding energy (kcal/mol)	Hydrogen bonds
MMP7	Scu	-8.3	6
MMP9	Scu	-8.8	6
LCN2	Scu	-8.2	2
SELE	Scu	-7.1	6

图6 Scu与关键治疗基因(KT基因)蛋白质受体的分子对接

Fig.6 Molecular docking of scutellarin with the protein receptor of the key therapeutic genes. A: Molecular docking display diagram of MMP7. B: Molecular docking display diagram of MMP9. C: Molecular docking display diagram of LCN2. D: Molecular docking display diagram of SELE.

图7 Scu与MMP7的分子动力学模拟

Fig.7 Molecular dynamics simulation of scutellarin and MMP7. A: Root mean square deviation (RMSD) of the protein backbone over time, indicating stabilization after approximately 10 ns. B: Radius of gyration analysis of the protein complex, which stabilizes at 1.46 nm, suggesting a stable complex structure. C: Solvent accessible surface area (SASA) analysis of the complex, remaining stable at approximately 92.5 nm². D: Residue fluctuation analysis of MMP7, showing higher flexibility around residues 165 and 167. E: Hydrogen bond analysis between scutellarin and MMP7, showing an average number of 4.469 hydrogen bonds. F: Free energy landscape.

图8 Scu与LCN2的分子动力学模拟

Fig.8 Molecular dynamics simulation of scutellarin and LCN2. A: RMSD of the protein backbone over time, indicating stabilization after approximately 20 ns. B: Radius of gyration analysis of the protein complex, which stabilizes at 1.54 nm, suggesting a stable complex structure. C: SASA analysis of the complex, remaining stable at approximately 107 nm². D: Residue fluctuation analysis of LCN2, showing higher flexibility around residues 100 and 103. E: Hydrogen bond analysis between scutellarin and LCN2, showing an average number of 8.989 hydrogen bonds. F: Free energy landscape.

图9 Scu与MMP9的分子动力学模拟

Fig.9 Molecular dynamics simulation of scutellarin and MMP9. A: RMSD of the protein backbone over time, indicating stabilization after approximately 7 ns. B: Radius of gyration analysis of the protein complex, which stabilizes at 1.8 nm, suggesting a stable complex structure. C: SASA analysis of the complex, remaining stable at approximately 128 nm². D: Residue fluctuation analysis of MMP9, showing higher flexibility around residue 179. E: Hydrogen bond analysis between scutellarin and MMP9, with an average number of 4.48 hydrogen bonds. F: Free energy landscape.

图10 Scu与SELE的分子动力学模拟

Fig.10 Molecular dynamics simulation of scutellarin and SELE. A: RMSD of the protein backbone over time, indicating stabilization after approximately 7 ns. B: Radius of gyration analysis of the protein complex, which stabilizes at 1.8 nm, suggesting a stable complex structure. C: SASA analysis of the complex, remaining stable at approximately 98 nm². D: Residue fluctuation analysis of SELE, showing higher flexibility around residue 84. E: Hydrogen bond analysis between scutellarin and SELE, showing an average number of 4.46 hydrogen bonds. F: Free energy landscape.

表3 大鼠肝组织NAS评分

Tab.3 NAS scores of rat liver tissues

Group	Steatosis	Inflammation	Ballooning	NAS Score	Pathological assessment
Control	0	0	0	0	Normal
Model	3	2-3	2	7	Marked NASH-like alterations
LD Scu	2	2	1	5	Moderate improvement
MD Scu	1	1	1	3	Significant improvement
HD Scu	0-1	0-1	0	1-2	Nearly normal
SIM	0-1	0-1	0	1-2	Trend toward normalization

图11 Scu对MASLD大鼠生化指标的影响

Fig.11 Effects of scutellarin on biochemical parameters in MASLD rats. A: Changes in liver-to-body weight ratio across different treatment groups. B: Effects of different scutellarin doses on liver function markers (ALT, AST, and ALP). C: Effects of different scutellarin doses on inflammatory cytokines (IL-1β, IL-6, and TNF-α). D: Effects of different scutellarin doses on serum lipid profiles (TG, TC, LDL, and HDL). E: Effects of different scutellarin doses on blood glucose, insulin levels, and insulin resistance. *P<0.05 vs Model. #P<0.05 vs Control.

图12 Scu对MASLD大鼠肝组织病理学改变的影响

Fig.12 Effects of scutellarin on histopathological alterations in liver tissues of MASLD rats. A: HE staining of liver sections from different treatment groups, showing a notable increase in fat vacuoles in the MASLD group, which was reduced following scutellarin treatment. B: Oil Red O staining of liver sections from different treatment groups, revealing severe hepatic steatosis in the MASLD group and obvious improvement after scutellarin treatment. C: Masson staining of liver sections from different treatment groups (scale bar=50 μm).

图13 Scu对MASLD大鼠肝组织MMP7和LCN2表达的影响

Fig.13 Effects of scutellarin on MMP7 and LCN2 expression in liver tissues of MASLD rats. A, B: qRT-PCR analysis of MMP7 and LCN2 mRNA expression levels in liver tissues from different treatment groups. C, D: Western blotting analysis of MMP7 and LCN2 protein expression levels in liver tissues from different treatment groups. #P<0.05 vs control group; *P<0.05 vs model group (n=10).

参考文献 47

[1]	Eslam M, Newsome PN, Sarin SK, et al. A new definition for metabolic dysfunction-associated fatty liver disease: an international expert consensus statement[J]. J Hepatol, 2020, 73(1): 202-9. doi：10.1016/j.jhep.2020.07.045
[2]	Cotter TG, Rinella M. Nonalcoholic fatty liver disease 2020: the state of the disease[J]. Gastroenterology, 2020, 158(7): 1851-64. doi：10.1053/j.gastro.2020.01.052
[3]	Rong L, Zou JY, Ran W, et al. Advancements in the treatment of non-alcoholic fatty liver disease (NAFLD)[J]. Front Endocrinol, 2023, 13: 1087260. doi：10.3389/fendo.2022.1087260
[4]	Ratziu V, Francque S, Sanyal A. Breakthroughs in therapies for NASH and remaining challenges[J]. J Hepatol, 2022, 76(6): 1263-78. doi：10.1016/j.jhep.2022.04.002
[5]	Wang R, Mao YH, Yu CP, et al. Research progress of natural products with the activity of anti-nonalcoholic steatohepatitis[J]. Mini Rev Med Chem, 2024, 24(21): 1894-929. doi：10.2174/0113895575306598240503054317
[6]	Liu TY, Sun YM, Zhao XY. Research progress on chemical components of Astragalus membranaceus and treatment of metabolic syndrome[J]. Molecules, 2025, 30(18): 3721. doi：10.3390/molecules30183721
[7]	Chen LZ, Pu XM, Li L, et al. Shenling Jianpiwei formula ameliorates metabolic associated fatty liver disease through modulation of the gut microbiota and attenuation of LPS-mediated inflammation[J]. Fitoterapia, 2025, 186: 106862. doi：10.1016/j.fitote.2025.106862
[8]	Guo C, Huang QX, Wang YS, et al. Therapeutic application of natural products: NAD+ metabolism as potential target[J]. Phytomedicine, 2023, 114: 154768. doi：10.1016/j.phymed.2023.154768
[9]	Wen L, He T, Yu AX, et al. Breviscapine: a review on its phytochemistry, pharmacokinetics and therapeutic effects[J]. Am J Chin Med, 2021, 49(6): 1369-97. doi：10.1142/s0192415x21500646
[10]	Yuan T, Yang HY, Li YP, et al. Scutellarin inhibits inflammatory PANoptosis by diminishing mitochondrial ROS generation and blocking PANoptosome formation[J]. Int Immunopharmacol, 2024, 139: 112710. doi：10.1016/j.intimp.2024.112710
[11]	Xie XH, Wang F, Ge WX, et al. Scutellarin attenuates oxidative stress and neuroinflammation in cerebral ischemia/reperfusion injury through PI3K/Akt-mediated Nrf2 signaling pathways[J]. Eur J Pharmacol, 2023, 957: 175979. doi：10.1016/j.ejphar.2023.175979
[12]	Zhou H, Chen X, Chen LZ, et al. Anti-fibrosis effect of scutellarin via inhibition of endothelial-mesenchymal transition on isoprenaline-induced myocardial fibrosis in rats[J]. Molecules, 2014, 19(10): 15611-23. doi：10.3390/molecules191015611
[13]	Mo J, Yang RH, Li F, et al. Scutellarin protects against vascular endothelial dysfunction and prevents atherosclerosis via antioxidation[J]. Phytomedicine, 2018, 42: 66-74. doi：10.1016/j.phymed.2018.03.021
[14]	Zhang XY, Huo ZJ, Luan HL, et al. Scutellarin ameliorates hepatic lipid accumulation by enhancing autophagy and suppressing IRE1α/XBP1 pathway[J]. Phytother Res, 2022, 36(1): 433-47. doi：10.1002/ptr.7344
[15]	Zhang X, Dong ZC, Fan H, et al. Scutellarin prevents acute alcohol-induced liver injury via inhibiting oxidative stress by regulating the Nrf2/HO-1 pathway and inhibiting inflammation by regulating the AKT, p38 MAPK/NF-κB pathways[J]. J Zhejiang Univ SCIENCE B, 2023, 24(7): 617-31. doi：10.1631/jzus.B2200612
[16]	Miao ZM, Lai Y, Zhao YY, et al. Protective property of scutellarin against liver injury induced by carbon tetrachloride in mice[J]. Front Pharmacol, 2021, 12: 710692. doi：10.3389/fphar.2021.710692
[17]	Kanehisa M, Bork P. Bioinformatics in the post-sequence era[J]. Nat Genet, 2003, 33(S3): 305-10. doi：10.1038/ng1109
[18]	Nogales C, Mamdouh ZM, List M, et al. Network pharmacology: curing causal mechanisms instead of treating symptoms[J]. Trends Pharmacol Sci, 2022, 43(2): 136-50. doi：10.1016/j.tips.2021.11.004
[19]	Fan XM, Wang YY, Li XF, et al. Scutellarin alleviates liver injury in type 2 diabetic mellitus by suppressing hepatocyte apoptosis in vitro and in vivo [J]. Chin Herb Med, 2023, 15(4): 542-8. doi：10.1016/j.chmed.2023.03.007
[20]	Wang YY, Fan XM, Fan B, et al. Scutellarin reduce the homocysteine level and alleviate liver injury in type 2 diabetes model[J]. Front Pharmacol, 2020, 11: 538407. doi：10.3389/fphar.2020.538407
[21]	Chen JYS, Chua D, Lim CO, et al. Lessons on drug development: a literature review of challenges faced in nonalcoholic fatty liver disease (NAFLD) clinical trials[J]. Int J Mol Sci, 2023, 24(1): 158. doi：10.3390/ijms24010158
[22]	Thorgersen EB, Barratt-Due A, Haugaa H, et al. The role of complement in liver injury, regeneration, and transplantation[J]. Hepatology, 2019, 70(2): 725-36. doi：10.1002/hep.30508
[23]	Bitto N, Liguori E, La Mura V. Coagulation, microenvironment and liver fibrosis[J]. Cells, 2018, 7(8): 85. doi：10.3390/cells7080085
[24]	Li N, Yamamoto G, Fuji H, et al. Interleukin-17 in liver disease pathogenesis[J]. Semin Liver Dis, 2021, 41(4): 507-15. doi：10.1055/s-0041-1730926
[25]	Hollenbach M. The role of glyoxalase-I (glo-I), advanced glycation endproducts (AGEs), and their receptor (RAGE) in chronic liver disease and hepatocellular carcinoma (HCC)[J]. Int J Mol Sci, 2017, 18(11): 2466. doi：10.3390/ijms18112466
[26]	Walke PB, Bansode SB, More NP, et al. Molecular investigation of glycated insulin-induced insulin resistance via insulin signaling and AGE-RAGE axis[J]. Biochim Biophys Acta BBA Mol Basis Dis, 2021, 1867(2): 166029. doi：10.1016/j.bbadis.2020.166029
[27]	Luan HL, Huo ZJ, Zhao ZF, et al. Scutellarin, a modulator of mTOR, attenuates hepatic insulin resistance by regulating hepatocyte lipid metabolism via SREBP-1c suppression[J]. Phytother Res, 2020, 34(6): 1455-66. doi：10.1002/ptr.6582
[28]	Irvine KM, Okano S, Patel PJ, et al. Serum matrix metalloproteinase 7 (MMP7) is a biomarker of fibrosis in patients with non-alcoholic fatty liver disease[J]. Sci Rep, 2021, 11: 2858. doi：10.1038/s41598-021-82315-z
[29]	Zheng CM, Lu KC, Chen YJ, et al. Matrix metalloproteinase-7 promotes chronic kidney disease progression via the induction of inflammasomes and the suppression of autophagy[J]. Biomed Pharmacother, 2022, 154: 113565. doi：10.1016/j.biopha.2022.113565
[30]	Ke B, Fan C, Yang L, et al. Corrigendum: matrix metalloproteinase-7 and kidney fibrosis[J]. Frontiers in Physiology, 2017, 8: 192. doi：10.3389/fphys.2017.00192
[31]	de Almeida LGN, Thode H, Eslambolchi Y, et al. Matrix metalloproteinases: from molecular mechanisms to physiology, pathophysiology, and pharmacology[J]. Pharmacol Rev, 2022, 74(3): 714-70. doi：10.1124/pharmrev.121.000349
[32]	Belaaouaj AA, Li AG, Wun TC, et al. Matrix metalloproteinases cleave tissue factor pathway inhibitor[J]. J Biol Chem, 2000, 275(35): 27123-8. doi：10.1016/s0021-9258(19)61488-2
[33]	Zhang Q, Liu S, Parajuli KR, et al. Interleukin-17 promotes prostate cancer via MMP7-induced epithelial-to-mesenchymal transition[J]. Oncogene, 2017, 36(5): 687-99. doi：10.1038/onc.2016.240
[34]	Rodriguez-Ramiro I, Pastor-Fernández A, López-Aceituno JL, et al. Pharmacological and genetic increases in liver NADPH levels ameliorate NASH progression in female mice[J]. Free Radic Biol Med, 2024, 210: 448-61. doi：10.1016/j.freeradbiomed.2023.11.019
[35]	Deng YL, Lu LQ, Zhu DD, et al. MafG/MYH9-LCN2 axis promotes liver fibrosis through inhibiting ferroptosis of hepatic stellate cells[J]. Cell Death Differ, 2024, 31(9): 1127-39. doi：10.1038/s41418-024-01322-5
[36]	Kim KE, Lee J, Shin HJ, et al. Lipocalin-2 activates hepatic stellate cells and promotes nonalcoholic steatohepatitis in high-fat diet-fed Ob/Ob mice[J]. Hepatology, 2023, 77(3): 888-901. doi：10.1002/hep.32569
[37]	Al Jaberi S, Cohen A, D'Souza C, et al. Lipocalin-2: Structure, function, distribution and role in metabolic disorders[J]. Biomed Pharmacother, 2021, 142: 112002. doi：10.1016/j.biopha.2021.112002
[38]	Sciarretta F, Ceci V, Tiberi M, et al. Lipocalin-2 promotes adipose-macrophage interactions to shape peripheral and central inflam-matory responses in experimental autoimmune encephalomyelitis[J]. Mol Metab, 2023, 76: 101783. doi：10.1016/j.molmet.2023.101783
[39]	Ma HT, Yan XY, Liu JC, et al. Secondary ferroptosis promotes thrombogenesis after venous injury in rats[J]. Thromb Res, 2022, 216: 59-73. doi：10.1016/j.thromres.2022.06.002
[40]	Zhao RY, Wei PJ, Sun X, et al. Role of lipocalin 2 in stroke[J]. Neurobiol Dis, 2023, 179: 106044. doi：10.1016/j.nbd.2023.106044
[41]	Stallhofer J, Friedrich M, Konrad-Zerna A, et al. Lipocalin-2 is a disease activity marker in inflammatory bowel disease regulated by IL-17A, IL-22, and TNF-α and modulated by IL23R genotype status[J]. Inflamm Bowel Dis, 2015: 1. doi：10.1097/mib.0000000000000515
[42]	Peng L, Wen L, Shi QF, et al. Scutellarin ameliorates pulmonary fibrosis through inhibiting NF‑κB/NLRP3-mediated epithelial-mesenchymal transition and inflammation[J]. Cell Death Dis, 2020, 11(11): 978. doi：10.1038/s41419-020-03178-2
[43]	Zhou Y, Gu CL, Zhu Y, et al. Pharmacological effects and the related mechanism of scutellarin on inflammation-related diseases: a review[J]. Front Pharmacol, 2024, 15: 1463140. doi：10.3389/fphar.2024.1463140
[44]	Su YM, Fan XM, Li SM, et al. Scutellarin improves type 2 diabetic cardiomyopathy by regulating cardiomyocyte autophagy and apoptosis[J]. Dis Markers, 2022, 2022: 3058354. doi：10.1155/2022/3058354
[45]	Hou YH, Gu DS, Peng JZ, et al. Ginsenoside Rg1 regulates liver lipid factor metabolism in NAFLD model rats[J]. ACS Omega, 2020, 5(19): 10878-90. doi：10.1021/acsomega.0c00529
[46]	Gu DS, Yi HA, Jiang KR, et al. Transcriptome analysis reveals the efficacy of ginsenoside-Rg1 in the treatment of nonalcoholic fatty liver disease[J]. Life Sci, 2021, 267: 118986. doi：10.1016/j.lfs.2020.118986
[47]	Wang JG, Li SD, Fan XM. Transcriptome analysis revealed the therapeutic effect of scutellarin on MASLD[J]. ACS Omega, 2025, 10(21): 21095-104. doi：10.1021/acsomega.4c09465

灯盏乙素通过调控MMP7与LCN2改善大鼠代谢功能障碍相关脂肪性肝病

Scutellarin improves metabolic dysfunction-associated steatotic liver disease in rats by regulating MMP7 and LCN2

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