RESUMO
BACKGROUND: The emergence of treatment resistance has hindered the efficacy of targeted therapies used to treat patients with hepatocellular carcinoma (HCC). OBJECTIVE: This study aimed to explore the mechanism of organoids constructed from lenvatinib-resistant HCC cells. METHODS: Hep3B cell and human HCC organoids were cultured and identified using hematoxylin and eosin staining and Immunohistochemistry. Lenvatinib-sensitive/ resistant Hep3B cells were constructed using lenvatinib (0, 0.1, 1, and 10 µM) and lenvatinib (0, 1, 10, and 100 µM). qRT-PCR and flow cytometry were utilized to determine HCC stem cell markers CD44, CD90, and CD133 expressions. Transcriptome sequencing was performed on organoids.-Western blot evaluated Notch pathwayrelated proteins (NOTCH1 and Jagged) expressions. Furthermore, DAPT, an inhibitor of the Notch pathway, was used to investigate the effects of lenvatinib on resistance or stemness in organoids and human HCC tissues. RESULTS: The organoids were successfully cultivated. With the increase of lenvatinib concentration, sensitive cell organoids were markedly degraded and ATP activity was gradually decreased, while there was no significant change in ATP activity of resistant cell organoids. CD44 expressions were elevated after lenvatinib treatment compared with the control group. KEGG showed that lenvatinib treatment of organoids constructed from Hep3B cells mainly activated the Notch pathway. Compared with the control group, NOTCH1 and Jagged expressions elevated, and ATP activity decreased after lenvatinib treatment. However, ATP activity was notably decreased after DAPT treatment. Moreover, DAPT inhibited lenvatinib resistance and the increase in the expressions of CD44 caused by lenvatinib. Besides, 100 µM lenvatinib significantly inhibited the growth and ATP activity of human HCC organoids, and DAPT increased the inhibitory effect of lenvatinib. CONCLUSION: Lenvatinib regulated resistance and stemness in organoids via the Notch pathway.
RESUMO
The objectives of our study were to investigate the roles of mTORC1 in odontoblast proliferation and mineralization and to determine the mechanism by which mTORC1 regulates odontoblast mineralization. In vitro, MDPC23 cells were treated with rapamycin (10 nmol/L) and transfected with a lentivirus for short hairpin (shRNA)-mediated silencing of the tuberous sclerosis complex (shTSC1) to inhibit and activate mTORC1, respectively. CCK8 assays, flow cytometry, Alizarin red S staining, ALP staining, qRT-PCR, and western blot analysis were performed. TSC1-conditional knockout (DMP1-Cre+ ; TSC1f/f , hereafter CKO) mice and littermate control (DMP1-Cre- ; TSC1f/f , hereafter WT) mice were generated. H&E staining, immunofluorescence, and micro-CT analysis were performed. Transcriptome sequencing analysis was used to screen the mechanism of this process. mTORC1 inactivation decreased the cell proliferation. The qRT-PCR and western blot results showed that mineralization-related genes and proteins were downregulated in mTORC1-inactivated cells. Moreover, mTORC1 overactivation promoted cell proliferation and mineralization-related gene and protein expression. In vivo, the micro-CT results showed that DV/TV and dentin thickness were higher in CKO mice than in controls and H&E staining showed the same results. Mineralization-related proteins expression was upregulated. Transcriptome sequencing analysis revealed that p53 pathway-associated genes were differentially expressed in TSC1-deficient cells. By inhibiting p53 alone or both mTORC1 and p53 with rapamycin and a p53 inhibitor, we elucidated that p53 acts downstream of mTORC1 and that mTORC1 thereby promotes odontoblast mineralization. Taken together, our findings demonstrate that the role of mTORC1 in odontoblast proliferation and mineralization, and confirm that mTORC1 upregulates odontoblast mineralization via the p53 pathway.