Abstract
Current toxicology and cancer biology investigations have focused on developing alternative models that better recapitulate the in vivo architecture of tissues and organs. The present study evaluated the anticancer effects of the flavone cirsimarin, which presented successful antitumor activity on breast tumor cells. We assessed the impact of flavone on cell viability, proliferation, and migration, as well as on DNA integrity and modulation of related cellular pathways. In the 2D model, cirsimarin reduced cell viability at concentrations ≥ 80 μM after 24 h of treatment (resazurin assay), selectively in A549 cells compared to MRC-5 non-tumor cells. Apoptosis was induced at concentrations ≥ 40 μM, and clonogenicity was reduced by approximately 50% only at 160 μM. In the wound healing assay, cirsimarin (1-80 μM) completely inhibited cell migration and induced DNA damage (comet assay). These apoptotic and anti-migratory effects were associated with the downregulation of key genes involved in cell proliferation, death, and extracellular matrix remodeling, including TNF-α (0.32-fold), TP53 (0.17-fold), MMP-2 (0.18-fold), MMP-9 (0.43-fold), and MMP-11 (0.04-fold), as revealed by RT-qPCR analysis. In the 3D model, after 216 h of treatment, cirsimarin reduced cell viability (≥ 40 μM) and spheroid area (≥ 80 μM) while antimigratory effects were observed only in the highest concentration evaluated (160 μM). These findings could indicate a potential reduction in lung tumor growth and metastasis, warranting further investigation, particularly of the antimetastatic effect of this flavone.