Therapeutic effect and mechanism of celecoxib on bladder cancer cell implanted mice

Abstract

Abstract: Objective To explore the therapeutic effect of celecoxib on mice implanted with bladder cancer cells and its related mechanism. Methods Sixty male BALB/c nude mice were randomly divided into three groups: control group, model group and observation group. The model group and the observation group were implanted with human bladder cancer cell line 5637 to establish a mouse bladder cancer model. The mice in the observation group were treated with celecoxib, while the mice in the control group and the model group were injected with the same dose of 0.9% sodium chloride solution. After 4 weeks of treatment, the tumor tissue of model group and experimental group and normal tissue of control group were taken to detect the expression of CD4⁺, CD8⁺, and the ratio of CD4⁺/CD8⁺ in the tissues of three groups. Western blot was performed to test the positive expression of COX-2, VEGF and cPLA2.TUNEL method was used to test the apoptotic rate of bladder cancer cells in model group and observation group. Results The mice in the control group grew normally without tumor under the skin. The tumorigenesis rate of model group and observation group was 100%. The tumor mass of the model group and the observation group were (2.08±0.36)g and (1.18±0.21)g. Compared with the model group, the tumor mass of mice in the observation group decreased significantly (P＜0.05). The tumor inhibition rate of mice in the observation group was 43.33%. The levels of CD4⁺, CD4⁺/CD8⁺ in tissue of model group and observation group was significantly lower than that of control group, and the level of CD8⁺ was significantly higher than that of control group (P＜0.05). The levels of CD4⁺, CD4⁺/CD8⁺ in tumor tissue of mice in the observation group were significantly higher than those in the model group, and the level of CD8⁺ was significantly lower than that in the model group (P＜0.05). COX-2 and cPLA2 protein levels were not expressed in tissues of mice in control group, the expression of VEGF protein was positive in all three groups. The expression levels of COX-2, VEGF and cPLA2 in the observation group were significantly lower than those in the model group, and the apoptotic index was significantly higher than that in the model group (P＜0.05). Conclusions Celecoxib has a certain inhibitory effect on implanted bladder cancer in mice. Its mechanism may be related to improving the immune system level of bladder cancer mice, alleviating inflammatory reaction and inducing cancer cell apoptosis.

Key words: celecoxib, human bladder cancer cell line 5637, bladder cancer, immune cells, apoptosis

CLC Number:

R737.14

LIANG Bing, LUO Hou-zhou. Therapeutic effect and mechanism of celecoxib on bladder cancer cell implanted mice[J]. Basic & Clinical Medicine, 2021, 41(2): 240-244.

References

[1] Trilla-Fuertes L, Gámez-Pozo A, Prado-Vázquez G, et al. Biological molecular layer classification of muscle-invasive bladder cancer opens new treatment opportunities[J]. BMC Cancer, 2019, 19:636. doi:10.1186/s12885-019-5858-z.
[2] Chiang CH, Yeh CY, Chung JG, et al. Amentoflavone induces apoptosis and reduces expression of anti-apoptotic and metastasis-associated proteins in bladder cancer[J]. Anticancer Res, 2019, 39:3641-3649. doi: 10.21873/anticanres.13512.
[3] Yakovlev PG, Klyushin DA, Vereshchako RI. Bladder sparing surgery in high-grade bladder cancer[J]. Exp Oncol, 2019, 41:160-165.
[4] 肖华光, 成浩, 李超, 等.塞来昔布放射增敏作用及其机制的研究进展[J]. 中南医学科学杂志, 2017,45:422-426.
[5] 周贺, 刘军, 柳雅玲, 等.塞来昔布联合紫杉醇诱导乳腺癌细胞凋亡的协同作用及其机制[J]. 吉林大学学报:医学版, 2016, 42:446-451.
[6] 王明复, 李艳秀, 杨述海.苦参碱对膀胱癌大鼠COX-2、cPLA2及PGDH蛋白表达水平的影响[J]. 中医学报, 2017, 32:1363-1367.
[7] Kalangi SK, Swarnakar NK, Sathyavathi R, et al. Synthesis, characterization, and biodistribution of quantum dot-celecoxib conjugate in mouse paw edema model[J]. Oxid Med Cell Longev, 2018: 3090517. doi: 10.1155/2018/3090517. eCollection 2018.
[8] Han J, Wang JZ, Yang X, et al. METTL3 promote tumor proliferation of bladder cancer by accelerating pri-miR221/222 maturation in m6A-dependent manner[J]. Mol Cancer, 2019, 18:110. doi: 10.1186/s12943-019-1036-9.
[9] Sui X, Lei L, Chen L, et al. Inflammatory microenviron-ment in the initiation and progression of bladder cancer[J]. Oncotarget, 2017, 8: 93279-93294.
[10] 詹磊, 程良斌, 蔡岳. 塞来昔布抑制COX-2和PD-1发挥抗肝癌作用[J]. 中国免疫学杂志, 2018, 34:595-599.
[11] Cesário JMS, Brito RBO, Malta CS, et al. A simple method to induce hypoxia-induced vascular endothelial growth factor-A (VEGF-A) expression in T24 human bladder cancer cells[J]. In Vitro Cell Dev Biol Anim, 2017, 53: 272-276.
[12] Agrawal U, Kumari N, Vasudeva P, et al. Overexpres-sion of COX2 indicates poor survival in urothelial bladder cancer[J]. Ann Diagn Pathol, 2018, 34:50-55.

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