Demet Cansaran-Duman

Usnic Acid induces dual-pathway apoptosis in SKOV-3 ovarian cancer cells via PARP1 inhibition and MAPK pathway activation

Introduction Due to its silent clinical progression and diagnosis often occurring at advanced stages, ovarian cancer continues to be a major contributor to gynecological cancer-related mortality worldwide. Recent evidence underscores the critical therapeutic value of targeting the interplay between DNA damage response pathways, particularly poly (ADP-ribose) polymerase 1 (PARP1), and mitogen-activated protein kinase (MAPK) signaling cascades. Methods In this study, we investigated the anti-cancer potential of the naturally derived small molecule usnic acid in a chemotherapy-resistant epithelial ovarian cancer model (SKOV-3 cells) at the cellular and molecular levels. Results Our findings demonstrate for the first time that usnic acid exerts a dual-pathway apoptotic mechanism by simultaneously inhibiting PARP1 and activating the MAPK signaling pathway. Remarkably, usnic acid mimics the gene-silencing action of siRNA on PARP1, suggesting a highly specific and potent inhibitory effect at the molecular level. Although ROS involvement and pathway causality were not directly tested, this dual-action profile enhances DNA damage-induced apoptosis and highlights usnic acid as a promising therapeutic candidate. Conclusion The study presents a novel molecular framework in which a single small molecule can coordinate apoptosis through parallel regulatory pathways, demonstrating the potential for innovative therapeutic approaches in the treatment of aggressive and treatment-resistant ovarian cancers.

Evernic Acid: A Low‐Toxic and Selective Alternative to Chemotherapeutic Agents in the Treatment of Ovarian Cancer

ABSTRACTEvernic acid (EA) has emerged as a potential therapeutic agent with its low toxicity and anticancer properties. In this study, the anticancer effect of EA on ovarian cancer cell lines and normal ovarian surface epithelial cells (OSE) was evaluated. The antiproliferative effect of EA was evaluated by xCELLigence Real‐Time Cell analysis, colony formation assay, and acridine orange and DAPI staining methods. Genotoxicity analysis was performed by comet assay. The effect of EA on cell migration was analyzed by wound healing assay. The potential of EA to induce apoptosis was also determined by evaluating the changes in gene and protein expression levels by qRT‐PCR and Western blot analysis, respectively. EA was found to be a promising potential therapeutic agent for ovarian cancer without showing significant cytotoxic effect on normal cells. Furthermore, EA decreased the ability of ovarian cancer cells for migration, increased the rate of apoptosis by inhibiting BIRC5 and activating CASP3, triggered cell cycle arrest in the G2/M phase, and caused a decrease in mitochondrial membrane potential and genotoxic effects. The results have shown that EA could be an effective candidate molecule for ovarian cancer treatment.