Mechanism of Mutant p53 Using Three-Dimensional Culture on Breast Cancer Malignant Phenotype via SREBP-Dependent Cholesterol Synthesis Pathway

In many cancers, including hormone sensitive tumors such as breast cancer, the “gain of function” caused by mutations in the tumor suppressor gene p53 plays an important role in the acquisition of malignant phenotypes and the regulation of cancer stem cell characteristics. However, its action of molecular mechanisms, particularly in vivo conditions, has not been fully clarified. Therefore, we focused on the “gain of function” of mutant p53 and the cholesterol biosynthesis pathway, especially the mevalonate(MVA) pathway, using breast cancer cells, and clarified the interaction between them and the relationship with cancer malignancy using 3D-culture. Here, we generated knock out and knock in breast cancer cell lines for p53 using CRISPR-Cas9 system, and then confirmed malignant morphological changes by 3D-culture model. We found that the introduction of mutant p53 was solely able to mediate the malignant transformation of cancer. Next, focusing on the relationship between cancer malignant transformation and lipid metabolism pathway, we investigated the role of the MVA pathway in malignant transformation by mutation p53. When investigating the effects of the addition of HMG-CoA inhibitors and isoprenoids, intermediate metabolites were important for malignant transformation during 3D culture. Furthermore, knockdown of SREBP2, which controls the MVA pathway, suppressed malignant phenotypes, so we proceeded with analysis of the interaction between mutant p53 and SREBP2. As the result, we found that mutant p53 and SREBP2 co-localize in the nucleus and consistently mutant p53 was associated with mevalonate pathway genes in parallel with binding pattern of SREBP2. Thus, our results provide the novel insight into the potential therapeutic targets for breast cancer with poor prognosis.