Effects of Sinomenine in Brassica rapa L. against Hypoxic Pulmonary Vascular Injury

doi:10.19803/j.1672-8629.20241025

Abstract

Abstract: Objective To observe the effects of interventions involving sinomenine in Brassica rapa L. on pulmonary vascular remodeling and pulmonary function in mice with hypoxic pulmonary vascular injury (HPVI). Methods Forty-eight mice were randomly divided into six groups: blank control group (Con), model group (Mod), sinomenine intervention low-, medium- and high-dose groups (L, M, H, at 50, 100, 150 mg·kg^-1 respectively), and dexamethasone (Dex) administration group. When hypoxia was terminated, routine blood tests, bronchoalveolar lavage fluid (BALF) examination, small animal ultrasound, blood oxygen saturation (SaO₂) measurement, blood biochemistry analysis, pulmonary tissue pathology examination, and immunohistochemistry were conducted. Western blot (WB) was used to detect the protein expressions of HIF-1α, VEGFA, Ang2, IL-1β, and NF-κB to find out about the mechanism of action. High-resolution mass spectrometry (HRMS) technology was employed for quantitative analysis of sinomenine in Brassica rapa L. Results The content of sinomenine in a 1 g·mL^-1 aqueous extract sample of Brassica rapa L. was 3.558 mg·mL^-1. Sinomenine reduced the numbers of such inflammatory cells as WBCs, NEUTs, and lymphocytes in the serum of HPVI mice. It could significantly lower the cell count in the alveolar lavage fluid and the levels of ALP and LDH. It enhanced the cardiopulmonary function and oxygen saturation of mice, but decreased the frequency of respiration. Furthermore, sinomenine mitigated pathological injury in lung tissues, and significantly reduced the percentage of the area and thickness of the vascular wall. Compared with the model group, sinomenine interventions significantly lowered the protein expression levels of HIF-1α, Ang2, VEGFA, and IL-1β, as well as NF-κB in lung tissues of HPVI mice. Conclusion Sinomenine interventions can effectively inhibit vascular remodeling in HPVI mice, especially in the medium dose group. Sinomenine can regulate vascular homeostasis, improve vascular permeability, enhance cardiopulmonary function, facilitate oxygen uptake and transport, and induce vascular normalization by reducing the expressions of angiogenic factors in lung tissues of mice.

Key words: Sinomenine, Brassica rapa L., Hypoxic Pulmonary Vascular Injury, Vascular Remodeling, Mice

CLC Number:

LIN Lin, YANG Tingyu, GAO Rong, MA Zengchun, SHEN Xin, GAO Yue. Effects of Sinomenine in Brassica rapa L. against Hypoxic Pulmonary Vascular Injury[J]. Chinese Journal of Pharmacovigilance, 2025, 22(6): 608-613.

Add to citation manager EndNote|Ris|BibTeX

URL: https://zgywjj.magtechjournal.com/EN/10.19803/j.1672-8629.20241025

https://zgywjj.magtechjournal.com/EN/Y2025/V22/I6/608

References

[1] HARTMAN-KSYCIŃSKA A, KLUZ-ZAWADZKA J, LEWANDOWSKI B. High Altitude Illness[J]. Przegl Epidemiol, 2016, 70(3): 490-499.
[2] MALLET RT, BURTSCHER J, PIALOUX V, et al.Molecular Mechanisms of High-Altitude Acclimatization[J]. International Journal of Molecular Sciences, 2023, 24(2): 1698.
[3] LIU R, XU C, ZHANG W, et al.FUNDC1-Mediated Mitophagy and HIF1α Activation Drives Pulmonary Hypertension during Hypoxia[J]. Cell Death and Disease, 2022, 13(7): 634.
[4] SURESH MV, BALIJEPALLI S, SOLANKI S, et al.Hypoxia-Inducible Factor 1α and Its Role in Lung Injury: Adaptive or Maladaptive[J]. Inflammation, 2023, 46(2): 491-508.
[5] CAO J, LUO JY, WU D, et al.Effect of Vascular Endothelial Growth Factor A on Pulmonary Vascular Remodeling in Neonatal Rats with Hypoxic Pulmonary Hypertension and Its Mechanism[J]. Chinese Journal of Pediatrics(中国当代儿科杂志), 2021, 23(1): 103-110.
[6 ] LI CY, CAO WJ, HUANG Y, et al. Study on the Intervention Effect of Dabufei Decoction on Acute Lung Injury in Rats with High Altitude Hypoxia Based on HIF-1α/NLRP3 Signaling Pathway[J]. Chinese Journal of Modern Applied Pharmacy(中国现代应用药学), 2024, 41(6): 736-742.
[7] PENG Y.A Critical Review on Phytochemical Profile and Biological Effects of Turnip (Brassica rapa L.)[J]. Frontiers in Nutrition, 2021, 29(8): 721-733.
[8] WANG S, ZHANG L, ZHOU Y, et al.A Review on Pharmacokinetics of Sinomenine and Its Anti-Inflammatory and Immunomodulatory Effects[J]. International Immunopharmacology, 2023, 119: 110-227.
[9] GUAN JJ.Protective Effect and Mechanism of Sinomenine on Acute Lung Injury in Mice[J]. Zhejiang Journal of Integrated Chinese and Western Medicine(浙江中西医结合杂志), 2020, 30(9): 709-712.
[10] ZENG Q, XIAO W, JIANG Y.Effect of Sinomenine Hydrochloride on Lung Injury in Sepsis Mice[J]. Chinese Journal of Clinical Pharmacology(中国临床药理学杂志), 2021, 37(18): 2468-2471.
[11] WILKINS MR, GHOFRANI HA, WEISSMANN N, et al.Pathop-hysiology and Treatment of High-Altitude Pulmonary Vascular Disease[J]. Circulation, 2015, 131(6): 582-590.
[12] DUNHAM-SNARY KJ, WU D, SYKES EA, et al.Hypoxic Pulmonary Vasoconstriction[J]. Chest, 2017, 151(1): 181-192.
[13] CHEN B, YUAN DZ, FU Y.Effect of Stage Intervention of Yunyao Tianlong exhaustion on Lung Tissue Remodeling and Lung Function in Rats with Pulmonary Fibrosis[J]. Chinese Journal of Pharmacovigilance(中国药物警戒), 2024, 21(5): 540-546.
[14] SU Y, LUCAS R, FULTON DJR, et al.Mechanisms of Pulmonary Endothelial Barrier Dysfunction in Acute Lung Injury and Acute Respiratory Distress Syndrome[J]. Chinese Medical Journal: Pulmonary and Critical Care Medicine, 2024, 2(2): 80-87.
[15] YE Y, XU Q, WUREN T.Inflammation and Immunity in the Pathogenesis of Hypoxic Pulmonary Hypertension[J]. Frontiers in Immunology, 2023, 5(14): 1162556.
[16] POSEY JN, JORDAN M, LEWIS CV, et al.Nbeal2 Knockout Mice Are not Protected Against Hypoxia-Induced Pulmonary Vascular Remodeling and Pulmonary Hypertension[J]. Blood Advances, 2025, 9(7): 1571-1584.
[17] NA L, XIONG Z, QING H.Vascular Endothelial Growth Factor and High-Altitude Pulmonary Edema[J]. Advances in Cardiovascular Diseases(心血管病学进展), 2019, 40(2): 188-191.
[18] LIU J, WANG W, WANG L, et al.IL-33 Initiates Vascular Remodelling in Hypoxic Pulmonary Hypertension by up-Regulating HIF-1α and VEGF Expression in Vascular Endothelial Cells[J]. EBioMedicine, 2018, 33: 196-210.
[19] SONG ZF, LI ZP.Research Progress of Traditional Chinese Medicine in Inhibiting Angiogenesis of Liver Cancer Based on the HIF-1α/VEGF Pathway[J]. Traditional Medicine of Asia and the Pacific(亚太传统医药), 2022, 18(9): 201-206.

[1]	HU Haipeng, YAO Weijie, FENG Xin. Effects of Yangxue Antai Prescription on Placental Ferroptosis in Recurrent Spontaneous Abortion Mice [J]. Chinese Journal of Pharmacovigilance, 2025, 22(6): 621-626.
[2]	ZHAO Ronghua, ZHU Chunxu, SUN Jing, BAO Lei, WANG Xinwei, GENG Zihan, ZHANG Jingsheng, GUO Shanshan, LI Shuran, WANG Daohan, CUI Xiaolan. Mechanisms of Sanhan Huashi Granules on a Respiratory Syncytial Virus and Influenza Virus and Respiratory Syncytial Virus Induced Pneumonia Model in Mice [J]. Chinese Journal of Pharmacovigilance, 2025, 22(5): 488-494.
[3]	CHEN Runji, SUN Xiaorui, HUANG Xin, JIANG Zhenzhou, ZHANG Luyong, WANG Xinzhi, DING Jian. Dynamic Immunophenotyping of NK Cells in Triptolide-Induced Hepatotoxicity [J]. Chinese Journal of Pharmacovigilance, 2025, 22(5): 517-522.
[4]	TANG Qianhui, ZHU Ying, ZHANG Haoran, ZHANG Luyong, JIANG Zhenzhou. Roles of Hepatocellular NF-κB Signaling Pathway in Triptolide-Induced Indirect Liver Injury [J]. Chinese Journal of Pharmacovigilance, 2025, 22(2): 128-138.
[5]	LIANG Xiaojing, CHEN Xin, NONG Cheng, LI Liang, DING Jian, ZHANG Luyong, JIANG Zhenzhou, WANG Xinzhi. Screening of in vitro Stimulation Methods for iNKT Cells and Conditions for in vitro Activation of iNKT Cells by Triptolide [J]. Chinese Journal of Pharmacovigilance, 2025, 22(2): 147-154.
[6]	HOU Tiantian, WANG Xudong, YANG Ping, ZHOU Pengbo, QIN Chao, HUANG Ying, WANG Ailing, GENG Xingchao, ZHOU Xiaobing, LIU Defang. Biodistribution of Therapeutic DNA Vaccines in Mice [J]. Chinese Journal of Pharmacovigilance, 2025, 22(1): 58-66.
[7]	CAI Haili, ZHANG Xiaomeng, LIU Yadi, LIU Shujia, GAO Fujun, WANG Yu, ZHANG Bing. Progress in construction and evaluation of a drug-induced cardiotoxicity model [J]. Chinese Journal of Pharmacovigilance, 2024, 21(7): 765-770.
[8]	YUAN Zhexin, WANG Wenqing, HUANG Yifan, ZHANG Rongzhen, TANG Yucheng, ZHANG Linghan, ZHANG Haiying, LIU Yan. MCOLN1 ameliorates atherosclerosis by regulating lysosomal autophagy [J]. Chinese Journal of Pharmacovigilance, 2024, 21(7): 781-786.
[9]	XIE Zhiqiang, YUAN Jiqiao, LI Jialin, LIU Zhengyue, WANG Manyuan. Therapeutic effect and immune mechanism of artemisia annua L. ointment on mouse eczema models [J]. Chinese Journal of Pharmacovigilance, 2024, 21(6): 617-624.
[10]	LIU Yang, FAN Zheng, WANG Honglei, YANG Ying, GUO Qi, CHANG Xinyu, HAN Lijuan, LI Wenzhe, WU Jiankun. Therapeutic effect of Jingzhui Kangfu pills against osteoarthritis induced by proteoglycan in mice [J]. Chinese Journal of Pharmacovigilance, 2024, 21(6): 651-654.
[11]	LI Shuran, GUO Shanshan, ZHAO Ronghua, BAO Lei, SUN Jing, GENG Zihan, BAO Yanyan, PANG Bo, CHEN Mengping, LYU Yaozhong, WANG Zhenzhong, CUI Xiaolan, WANG Hongmei. Roles of Foshao granules in regulating gut microbiota and lactase activity in mice [J]. Chinese Journal of Pharmacovigilance, 2024, 21(6): 655-659.
[12]	CHEN Bing, YUAN Dezheng, FU Yi. Effect of Tianlongjie stage interventions on lung tissue remodeling and lung function of pulmonary fibrosis rats [J]. Chinese Journal of Pharmacovigilance, 2024, 21(5): 540-546.
[13]	YAO Weijie, YAN Shiqi, YUAN Sisi, GONG Leilei, FENG Xin. Roles of Yangxue Antai prescription in improving endometrial epithelial-mesenchymal transformation and decidualization in recurrent spontaneous abortion mice by regulating autophagy [J]. Chinese Journal of Pharmacovigilance, 2024, 21(5): 547-552.
[14]	YAO Weijie, YAN Shiqi, YUAN Sisi, GONG Leilei, FENG Xin. Effect of Yangxue Antai prescription on the regulation of placental angiogenesis and autophagy in recurrent spontaneous abortion mice [J]. Chinese Journal of Pharmacovigilance, 2024, 21(4): 371-377.
[15]	HUANG Shuguang, ZHANG Xuenong. Pharmacodynamics of peptide drug BR0336 in a mouse model of T2DM combined with NASH [J]. Chinese Journal of Pharmacovigilance, 2024, 21(4): 415-421.