Horacio Cardenas

Metabolic Dependency on De Novo Pyrimidine Synthesis Is a Targetable Vulnerability in Platinum-Resistant Ovarian Cancer

Abstract Ovarian cancer is lethal because of near-universal development of resistance to platinum-based chemotherapy. Metabolic adaptations can play a pivotal role in therapy resistance. In this study, we aimed to identify key metabolic pathways that regulate platinum response and represent potential therapeutic targets. Transcriptomic and metabolomic analyses in cisplatin-sensitive and -resistant ovarian cancer cells identified enrichment of pyrimidine metabolism related to upregulated de novo pyrimidine synthesis. The 15N-glutamine flux analysis confirmed increased de novo pyrimidine synthesis in cisplatin-resistant cells. Targeting this pathway using brequinar (BRQ), an inhibitor of the key enzyme dihydroorotate dehydrogenase, decreased cell viability, delayed G2/M cell-cycle progression, and altered expression of genes related to mitochondrial electron transport in resistant cells. Under basal conditions, cisplatin-resistant cells had a lower oxygen consumption rate and spare respiratory capacity than cisplatin-sensitive cells. BRQ suppressed the oxygen consumption rate in both sensitive and resistant cells but only inhibited spare respiratory capacity in resistant cells. In cell line–derived and patient-derived xenograft models, BRQ attenuated the growth of cisplatin-resistant ovarian tumors and enhanced the inhibitory effects of carboplatin. Together, these results identify metabolic reprogramming in cisplatin-resistant ovarian cancer that induces an acquired dependency on de novo pyrimidine synthesis, which can be targeted to sensitize tumors to chemotherapy. Significance: De novo pyrimidine synthesis supports platinum resistance in ovarian cancer and can be targeted with DHODH inhibitors to suppress tumor growth, pointing to potential metabolic therapies for treating recurrent ovarian cancer.

Preclinical Evaluation of NTX-301, a Novel DNA Hypomethylating Agent in Ovarian Cancer

Abstract Purpose: DNA methylation causes silencing of tumor-suppressor and differentiation-associated genes, being linked to chemoresistance. Previous studies demonstrated that hypomethylating agents (HMA) resensitize ovarian cancer to chemotherapy. NTX-301 is a highly potent and orally bioavailable HMA, in early clinical development. Experimental Design: The antitumor effects of NTX-301 were studied in ovarian cancer models by using cell viability, stemness and ferroptosis assays, RNA sequencing, lipidomic analyses, and stimulated Raman spectroscopy. Results: Ovarian cancer cells (SKOV3, IC50 = 5.08 nmol/L; OVCAR5 IC50 = 3.66 nmol/L) were highly sensitive to NTX-301 compared with fallopian tube epithelial cells. NTX-301 downregulated expression of DNA methyltransferases 1–3 and induced transcriptomic reprogramming with 15,000 differentially expressed genes (DEG, P < 0.05). Among them, Gene Ontology enrichment analysis identified regulation of fatty acid biosynthesis and molecular functions related to aldehyde dehydrogenase (ALDH) and oxidoreductase, known features of cancer stem cells. Low-dose NTX-301 reduced the ALDH(+) cell population and expression of stemness-associated transcription factors. Stearoyl-coenzyme A desaturase 1 (SCD), which regulates production of unsaturated fatty acids (UFA), was among the top DEG downregulated by NTX-301. NTX-301 treatment decreased levels of UFA and increased oxidized lipids, and this was blunted by deferoxamine, indicating cell death via ferroptosis. NTX-301–induced ferroptosis was rescued by oleic acid. In vivo, monotherapy with NTX-301 significantly inhibited ovarian cancer and patient-derived xenograft growth (P < 0.05). Decreased SCD levels and increased oxidized lipids were detected in NTX-301–treated xenografts. Conclusions: NTX-301 is active in ovarian cancer models. Our findings point to a new mechanism by which epigenetic blockade disrupts lipid homeostasis and promotes cancer cell death.

N6-Methyladenosine RNA Modifications Regulate the Response to Platinum Through Nicotinamide N-methyltransferase

Abstract Development of resistance to platinum (Pt) in ovarian cancer remains a major clinical challenge. Here we focused on identifying epitranscriptomic modifications linked to Pt resistance. Fat mass and obesity-associated protein (FTO) is a N6-methyladenosine (m6A) RNA demethylase that we recently described as a tumor suppressor in ovarian cancer. We hypothesized that FTO-induced removal of m6A marks regulates the cellular response of ovarian cancer cells to Pt and is linked to the development of resistance. To study the involvement of FTO in the cellular response to Pt, we used ovarian cancer cells in which FTO was knocked down via short hairpin RNA or overexpressed and Pt-resistant (Pt-R) models derived through repeated cycles of exposure to Pt. We found that FTO was significantly downregulated in Pt-R versus sensitive ovarian cancer cells. Forced expression of FTO, but not of mutant FTO, increased sensitivity to Pt in vitro and in vivo (P < 0.05). Increased numbers of γ-H2AX foci, measuring DNA double-strand breaks, and increased apoptosis were observed after exposure to Pt in FTO-overexpressing versus control cells. Through integrated RNA sequencing and MeRIP sequencing, we identified and validated the enzyme nicotinamide N-methyltransferase (NNMT), as a new FTO target linked to Pt response. NNMT was upregulated and demethylated in FTO-overexpressing cells. Treatment with an NNMT inhibitor or NNMT knockdown restored sensitivity to Pt in FTO-overexpressing cells. Our results support a new function for FTO-dependent m6A RNA modifications in regulating the response to Pt through NNMT, a newly identified RNA methylated gene target.