黄芩素对人舌鳞状细胞癌CAL27细胞增殖的抑制作用及其机制

doi:10.13481/j.1671-587X.20230420

Abstract

Abstract:

Objective To discuss the effect of baicalin on the proliferation of the human tongue squamous cell carcinoma （tongue squamous cell carcinoma） CAL27 cells， and to clarify its potential mechanism. Methods The CAL27 cells at logarithmic growth phase were divided into control group and different concentrations （12.5， 25.0， 50.0， 100.0， and 200.0 μmol·L^－1） of baicalein groups， the clone formation of cells in various groups was observed by crystal violet staining； the proliferation rates of cells in various groups were detected by CCK-8 method；the levels of reactive oxygen species （ROS） in cells in vaious groups were detected by 2'， 7'-dichlorofluorescein diacetate （DCFH-DA） fluorescence probe； the mitochondrial membrane potential （MMP） of cells in various groups were detected by Rhodamine 123 fluorescence probe. The CAL27 cells at logarithmic growth phase were divided into control group and different concentrations （50， 100， and 200 μmol·L^－1） of baicalin groups. Flow cytometry was used to detect the percentages of the cells at different cell cycles and the apoptotic rates of cells in various groups. The CAL27 cells at logarithmic growth phase were divided into control group and different concentrations （50 and 100 μmol·L^－1） of baicalein groups， N-neneneba acetylcysteine （NAC） group， 50 μmol·L^－1 baicalin+NAC group，and 100 μmol·L^－1 baicalin+NAC group. The levels of ROS and MMP of cells in vraious groups were detected by DCFH-DA fluorescence probe and Rhodamine 123 fluorescence probe. Results The crystal violet staining results showed that compared with control group， the numbers of clone formation of the cells in different concentrations of baicalin groups were decreased in a concentration-dependent manner， and there was almost no clone formation of the cells in 200 μmol·L^－1 baicalin group.The CCK-8 assay results showed that compared with control group， the proliferation rates of the cells in different concentrations of baicalin groups were significantly decreased in a concentration-dependent manner（P<0.05 or P<0.01）. Compared with control group， the ROS levels of the cells in different concentrations of baicalin groups were significantly increased（P<0.05） and the MMP levels were significantly decreased （P<0.05）. Compared with control group， the percentages of the cells at S phase in different concentrations of baicalin groups were significantly increased（P<0.05）， the percentages of the cells at G₀/G₁ phase were significantly decreased （P<0.05）， and the apoptotic rates were significantly increased （P<0.05）. After the combination of baicalein and NAC， compared with control group，the ROS levels of the cells in 50 and 100 μmol·L^－1 baicalein groups were significantly increased （P<0.05） and the MMP levels were significantly decreased （P<0.05）；compared with 50 and 100 μmol·L^－1 baicalein groups， the ROS levels of the cells in 50 μmol·L^－1 baicalein+NAC group and 100 μmol·L^－1 baicalein+NAC group were significantly decreased （P<0.05），and the MMP levels were significantly increased （P<0.05）. Conclusion Baicalein can inhibit the proliferation of the CAL27 cells by activating the mitochondrial oxidative stress pathway.

Key words: Baicalien, Oral squamous cell carcinoma, Cell cycle, Reactive oxygen species, Mitochondrial membrane potential

CLC Number:

R739.86

Naixu SHI,Miao HAO,Tianfu ZHANG,Kelin ZHAO,Ziyan HUANG,Chunyan LI,Xiaofeng WANG. Inhibitory effect of baicalein on proliferation of human tongue squamous cell carcinoma CAL27 cells and its mechanism[J].Journal of Jilin University(Medicine Edition), 2023, 49(4): 985-993.

Figures/Tables 9

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References 31

1	JOHNSON D E， BURTNESS B， LEEMANS C R，et al.Head and neck squamous cell carcinoma ［J］. Nat Rev Dis Primers， 2020， 6（1）： 92.
2	KITAMURA N， SENTO S， YOSHIZAWA Y， et al. Current trends and future prospects of molecular targeted therapy in head and neck squamous cell carcinoma［J］. Int J Mol Sci， 2020， 22（1）： 240.
3	BARADARAN RAHIMI V， ASKARI V R， HOSSEINZADEH H. Promising influences of Scutellaria baicalensis and its two active constituents， baicalin， and baicalein， against metabolic syndrome： a review［J］. Phytother Res， 2021， 35（7）： 3558-3574.
4	LIU B Y， LI L， LIU G L， et al. Baicalein attenuates cardiac hypertrophy in mice via suppressing oxidative stress and activating autophagy in cardiomyocytes［J］. Acta Pharmacol Sin， 2021， 42（5）： 701-714.
5	YU Z J， LI Q， WANG Y， et al. A potent protective effect of baicalein on liver injury by regulating mitochondria-related apoptosis［J］. Apoptosis， 2020，25（5/6）： 412-425.
6	DINDA B， DINDA S， DASSHARMA S， et al. Therapeutic potentials of baicalin and its aglycone， baicalein against inflammatory disorders［J］. Eur J Med Chem， 2017， 131： 68-80.
7	SU M Q， ZHOU Y R， RAO X， et al. Baicalein induces the apoptosis of HCT116 human colon cancer cells via the upregulation of DEPP/Gadd45a and activation of MAPKs［J］. Int J Oncol， 2018， 53（2）： 750-760.
8	CHEN Y， ZHANG J Y， ZHANG M Q， et al. Baicalein resensitizes tamoxifen-resistant breast cancer cells by reducing aerobic glycolysis and reversing mitochondrial dysfunction via inhibition of hypoxia-inducible factor-1α［J］. Clin Transl Med， 2021， 11（11）： e577.
9	GAO Z L， ZHANG Y Q， ZHOU H， et al. Baicalein inhibits the growth of oral squamous cell carcinoma cells by downregulating the expression of transcription factor Sp1［J］. Int J Oncol， 2020， 56（1）： 273-282.
10	LI B， LU M， JIANG X X， et al. Inhibiting reactive oxygen species-dependent autophagy enhanced baicalein-induced apoptosis in oral squamous cell carcinoma［J］. J Nat Med， 2017， 71（2）： 433-441.
11	SUENAGA N， KURAMITSU M， KOMURE K， et al. Loss of tumor suppressor CYLD expression triggers cisplatin resistance in oral squamous cell carcinoma［J］. Int J Mol Sci， 2019， 20（20）： 5194.
12	HUNG C C， CHIEN C Y， CHU P Y， et al. Differential resistance to platinum-based drugs and 5-fluorouracil in p22 phox-overexpressing oral squamous cell carcinoma： implications of alternative treatment strategies［J］. Head Neck， 2017， 39（8）： 1621-1630.
13	ATANASOV A G， ZOTCHEV S B， DIRSCH V M， et al. Natural products in drug discovery： advances and opportunities［J］.Nat Rev Drug Discov，2021，20（3）：200-216.
14	WANG Y S， ZHANG Q F， CHEN Y C， et al. Antitumor effects of immunity-enhancing traditional Chinese medicine［J］. Biomed Pharmacother， 2020， 121： 109570.
15	HARADA K， FERDOUS T， KOBAYASHI H， et al. Paclitaxel in combination with cetuximab exerts antitumor effect by suppressing NF-κB activity in human oral squamous cell carcinoma cell lines［J］. Int J Oncol， 2014， 45（6）： 2439-2445.
16	LEDWITCH K， OGBURN R， COX J， et al. Taxol： efficacy against oral squamous cell carcinoma［J］. Mini Rev Med Chem， 2013， 13（4）： 509-521.
17	SHANG Y， JIANG Y L， YE L J， et al. Resveratrol acts via melanoma-associated antigen A12 （MAGEA12）/protein kinase B （Akt） signaling to inhibit the proliferation of oral squamous cell carcinoma cells［J］. Bioengineered， 2021， 12（1）： 2253-2262.
18	XIAO C， WANG L L， ZHU L F， et al. Curcumin inhibits oral squamous cell carcinoma SCC-9 cells proliferation by regulating miR-9 expression［J］. Biochem Biophys Res Commun，2014，454（4）： 576-580.
19	LI F S， WENG J K. Demystifying traditional herbal medicine with modern approach［J］. Nat Plants， 2017， 3： 17109.
20	CHENG C S， CHEN J， TAN H Y， et al. Scutellaria baicalensis and cancer treatment： recent progress and perspectives in biomedical and clinical studies［J］. Am J Chin Med， 2018， 46（1）： 25-54.
21	SINGH S， MEENA A， LUQMAN S. Baicalin mediated regulation of key signaling pathways in cancer［J］. Pharmacol Res， 2021， 164： 105387.
22	WANG Z， MA L M， SU M Q， et al. Baicalin induces cellular senescence in human colon cancer cells via upregulation of DEPP and the activation of Ras/Raf/MEK/ERK signaling［J］.Cell Death Dis，2018，9（2）： 217.
23	ZHAO F C， ZHAO Z X， HAN Y R， et al. Baicalin suppresses lung cancer growth phenotypes via miR-340-5p/NET1 axis［J］.Bioengineered，2021，12（1）： 1699-1707.
24	POPRAC P， JOMOVA K， SIMUNKOVA M， et al. Targeting free radicals in oxidative stress-related human diseases［J］.Trends Pharmacol Sci，2017，38（7）：592-607.
25	CHEUNG E C， VOUSDEN K H. The role of ROS in tumour development and progression［J］. Nat Rev Cancer， 2022， 22（5）： 280-297.
26	SIES H， JONES D P. Reactive oxygen species （ROS） as pleiotropic physiological signalling agents［J］. Nat Rev Mol Cell Biol， 2020， 21（7）： 363-383.
27	YANG S S， LIAN G J. ROS and diseases： role in metabolism and energy supply［J］. Mol Cell Biochem， 2020， 467（1/2）： 1-12.
28	SAKAMURU S， ATTENE-RAMOS M S， XIA M. Mitochondrial membrane potential assay［J］. Methods Mol Biol， 2016， 1473： 17-22.
29	ZOROV D B， JUHASZOVA M， SOLLOTT S J. Mitochondrial reactive oxygen species （ROS） and ROS-induced ROS release［J］. Physiol Rev， 2014， 94（3）： 909-950.
30	QUOILIN C， MOUITHYS-MICKALAD A， LÉCART S， et al. Evidence of oxidative stress and mitochondrial respiratory chain dysfunction in an in vitro model of sepsis-induced kidney injury［J］. Biochim Biophys Acta， 2014， 1837（10）： 1790-1800.
31	DENG X H， LIU J J， LIU L T， et al. Drp1-mediated mitochondrial fission contributes to baicalein-induced apoptosis and autophagy in lung cancer via activation of AMPK signaling pathway［J］.Int J Biol Sci，2020，16（8）： 1403-1416.

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Inhibitory effect of baicalein on proliferation of human tongue squamous cell carcinoma CAL27 cells and its mechanism

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