FF-10502, an Antimetabolite with Novel Activity on Dormant Cells, Is Superior to Gemcitabine for Targeting Pancreatic Cancer Cells.

In this paper, we report that 1-(2-deoxy-2-fluoro-4-thio-ß-d-arabinofuranosyl) cytosine (FF-10502), a pyrimidine nucleoside antimetabolite with a chemical structure similar to gemcitabine, shows beneficial anticancer activity via a novel mechanism of action on dormant cells. The growth inhibition of pancreatic cancer cell lines by FF-10502 (IC50, 60-330 nM) was moderately weaker than that by gemcitabine in vitro. In contrast, an in vivo orthotopic implantation model in mice with established human pancreatic cancer cell line, SUIT-2, revealed no mortality with FF-10502 intravenous treatment, which was related to regression of implanted tumor and little metastasis, whereas 75% of the mice treated with gemcitabine died by day 128. Two in vivo patient-derived xenograft models with gemcitabine-resistant pancreatic cancer cells also demonstrated complete tumor growth suppression with FF-10502, but only partial inhibition with gemcitabine. We also investigated the mechanism of action of FF-10502 by using dormant cancer cells, which are reportedly involved in the development of resistance to chemotherapy. In vitro serum starvation-induced dormant SUIT-2 cells developed resistance to gemcitabine even in combination with DNA damage inducers (DDIs; H2O2, cisplatin, and temozolomide). Interestingly, FF-10502 in combination with DDIs significantly induced concentration-dependent cell death in accordance with enhanced DNA damage. FF-10502 was far more potent than gemcitabine in inhibiting DNA polymerase ß, which may explain the difference in dormant cell injury, although further investigations for direct evidences are necessary. In conclusion, our study demonstrated the beneficial antitumor effects of FF-10502 in clinically relevant in vivo models, and suggests the importance of preventing DNA repair unlike gemcitabine.

A novel small-molecule inhibitor of NF-kappaB signaling.

The inducible transcription factor NF-kappaB regulates divergent signaling pathways including inflammatory response and cancer development. Selective inhibitors for NF-kappaB signaling are potentially useful for treatment of inflammation and cancer. NF-kappaB is canonically activated by preferential disposal of its inhibitory protein; IkappaB, which suppresses the nuclear translocation of NF-kappaB. IkappaBalpha (a major member of IkappaB family proteins) is phosphorylated with an IkappaB kinase (IKK) and subsequently polyubiquitylated by SCF(betaTrCP1) ubiquitin-ligase in the presence of E1 and E2 prior to proteasomal degradation. Here, we describe a novel inhibitor termed GS143, which suppressed IkappaBalpha ubiquitylation, but not IkappaBalpha phosphorylation, MDM2-directed p53 ubiquitylation, and proteasome activity in vitro. GS143 markedly suppressed the destruction of IkappaBalpha stimulated by TNFalpha and a set of downstream responses coupled to NF-kappaB signaling but not those of p53 and beta-catenin in vivo. Our results indicate that GS143 serves as an effective inhibitor of multiple pathways served by NF-kappaB signaling.