Chang-Suk Chae

Targeting Ovarian Neoplasms: Subtypes and Therapeutic Options

The ovary, as the primary organ responsible for reproduction and new life, plays a central role in female development, maturation, and health. Neoplasms arising from the ovary and its associated tissues exhibit substantial heterogeneity in their histopathological and molecular profiles, many of which remain poorly understood. This review aims to summarize recent advances in the understanding of genetic alterations underlying ovarian neoplasms and to explore therapeutic strategies informed by molecular biomarkers and tumor microenvironmental factors. A comprehensive literature search was performed, focusing on genomic alterations, biomarker-guided therapies, and tumor microenvironmental modulation in ovarian cancers. Emphasis was placed on studies addressing lipid mediator pathways and their roles in immune regulation and therapeutic response. Based on diagnostic classifications, recurrent alterations in TP53, MYC, PIK3CA, and KRAS are consistently observed across epithelial and germ cell ovarian tumors, whereas non-epithelial subtypes such as sex cord–stromal tumors (SCSTs) and small-cell carcinoma of the ovary, hypercalcemic type (SCCOHT), are predominantly associated with ARID1A and SMARCA4 mutations, respectively. These findings highlight distinct pathogenic mechanisms linked to specific genetic alterations and reveal potential therapeutic vulnerabilities. Moreover, lipid metabolism has been closely implicated in immune surveillance through STING signaling cascades within innate immune cells, suggesting that lipid mediators and their associated genes may represent promising therapeutic targets in ovarian cancers (OCs). Targeting lipid mediators could be particularly effective in relapsed OCs, as modulating innate immune cells within the tumor microenvironment (TME) may enhance immune surveillance and improve antitumor responses. Integrating genetic and microenvironmental insights offers a promising direction for developing more effective and personalized therapeutic strategies in OC.

Iron Chelation Therapy Elicits Innate Immune Control of Metastatic Ovarian Cancer

Abstract Iron accumulation in tumors contributes to disease progression and chemoresistance. Although targeting this process can influence various hallmarks of cancer, the immunomodulatory effects of iron chelation in the tumor microenvironment are unknown. Here, we report that treatment with deferiprone, an FDA-approved iron chelator, unleashes innate immune responses that restrain ovarian cancer. Deferiprone reprogrammed ovarian cancer cells toward an immunostimulatory state characterized by the production of type-I IFN and overexpression of molecules that activate NK cells. Mechanistically, these effects were driven by innate sensing of mitochondrial DNA in the cytosol and concomitant activation of nuclear DNA damage responses triggered upon iron chelation. Deferiprone synergized with chemotherapy and prolonged the survival of mice with ovarian cancer by bolstering type-I IFN responses that drove NK cell-dependent control of metastatic disease. Hence, iron chelation may represent an alternative immunotherapeutic strategy for malignancies that are refractory to current T-cell–centric modalities. Significance: This study uncovers that targeting dysregulated iron accumulation in ovarian tumors represents a major therapeutic opportunity. Iron chelation therapy using an FDA-approved agent causes immunogenic stress responses in ovarian cancer cells that delay metastatic disease progression and enhance the effects of first-line chemotherapy. See related commentary by Bell and Zou, p. 1771

Tumor-Derived Lysophosphatidic Acid Blunts Protective Type I Interferon Responses in Ovarian Cancer

Abstract Lysophosphatidic acid (LPA) is a bioactive lipid enriched in the tumor microenvironment of immunosuppressive malignancies such as ovarian cancer. Although LPA enhances the tumorigenic attributes of cancer cells, the immunomodulatory activity of this phospholipid messenger remains largely unexplored. Here, we report that LPA operates as a negative regulator of type I interferon (IFN) responses in ovarian cancer. Ablation of the LPA-generating enzyme autotaxin (ATX) in ovarian cancer cells reprogrammed the tumor immune microenvironment, extended host survival, and improved the effects of therapies that elicit protective responses driven by type I IFN. Mechanistically, LPA sensing by dendritic cells triggered PGE2 biosynthesis that suppressed type I IFN signaling via autocrine EP4 engagement. Moreover, we identified an LPA-controlled, immune-derived gene signature associated with poor responses to combined PARP inhibition and PD-1 blockade in patients with ovarian cancer. Controlling LPA production or sensing in tumors may therefore be useful to improve cancer immunotherapies that rely on robust induction of type I IFN. Significance: This study uncovers that ATX–LPA is a central immunosuppressive pathway in the ovarian tumor microenvironment. Ablating this axis sensitizes ovarian cancer hosts to various immunotherapies by unleashing protective type I IFN responses. Understanding the immunoregulatory programs induced by LPA could lead to new biomarkers predicting resistance to immunotherapy in patients with cancer. See related commentary by Conejo-Garcia and Curiel, p. 1841. This article is highlighted in the In This Issue feature, p. 1825