Experimental study on the inhibitory effects of anlotinib on thyroid cancer progression and its induction of redifferentiation
10.3760/cma.j.cn321828-20240326-00116
- VernacularTitle:安罗替尼抑制甲状腺癌进展并诱导其再分化的实验研究
- Author:
Yutong XU
1
;
Jiang WU
;
Jun CHEN
;
Bo LUO
;
Feng WANG
;
Jun ZHANG
Author Information
1. 南京中医药大学附属泰州市人民医院核医学科,泰州 225300
- Publication Type:Journal Article
- Keywords:
Thyroid neoplasms;
Protein kinase inhibitors;
Indoles;
Tumor cells, cultured;
Mice, nude;
Anlotinib
- From:
Chinese Journal of Nuclear Medicine and Molecular Imaging
2025;45(4):229-233
- CountryChina
- Language:Chinese
-
Abstract:
Objective:To explore the effects of anlotinib on the proliferation, apoptosis, and migration of thyroid cancer cells, and investigate its role in inducing redifferentiation and enhancing iodine uptake capacity, providing a preliminary evaluation of its efficacy in tumor treatment.Methods:(1)The cell proliferation was detected by cell counting kit-8 (CCK-8) assay, and different concentrations (0, 1/4 half maximal inhibitory concentration (IC 50), 1/2IC 50, IC 50) of anlotinib were used to treat CAL62 and FTC133 thyroid cancer cells for 24h. The clonogenic formation experiment, cellular activity and drug toxicity staining, scratch healing assay, and apoptosis in situ fluorescence staining were employed to assess cell clonogenicity, apoptosis, and migration abilities. (2) CAL62 and FTC133 cells were treated with various concentrations of anlotinib, and changes in the expression levels of iodine metabolism-related proteins (sodium/iodide symporter (NIS), thyroid peroxidase (TPO), and thyroid-stimulating hormone receptor (TSHR)) were detected using Western blot. (3) Iodine uptake experiments were conducted to observe changes in the iodine uptake functionality of thyroid cancer cells following treatment with different concentrations of anlotinib for 24 h. (4) The thyroid cancer xenograft nude mouse models were established and divided into control group (physiological saline), low-dose group (1mg/kg), medium-dose group (2mg/kg), and high-dose group (4mg/kg). Mice were treated with varying doses of the drug, the therapeutic effects and the changes in iodine harvesting function on tumors were evaluated. One-way analysis of variance was used for comparison among groups. Results:Anlotinib treatment resulted in significantly reduced cell viability, decreased clonogenic formation, increased apoptosis rates, and reduced scratch healing rates in CAL62 and FTC133 cells ( F values: 53.75-211.90, all P<0.001). After anlotinib treatment, the levels of iodine metabolism-related proteins (NIS, TPO and TSHR) significantly increased ( F values: 21.14-710.00, all P<0.001), and iodine uptake rates in thyroid cancer cells also increased significantly ( F values: 36.45, 32.34, both P<0.001). The nude mouse treatment experiment showed tumor growth in the anlotinib treatment group was inhibited, and tumors iodine uptake rates were increased, both were statistically significant ( F values: 74.09, 38.22, both P<0.001). Conclusions:Anlotinib can inhibit thyroid cancer proliferation and growth, promote apoptosis, reduce cell migration capabilities, induce thyroid cancer cells redifferentiation, and enhance iodine uptake capacity. Anlotinib can induce the redifferentiation of thyroid cancer at the animal level and has better efficacy.
