Abstract 2706: Thermodynamic and molecular orbital analysis of the effects caused by incorporation of novel anti-tumor agent Trifluridine to DNA

Abstract

Abstract Trifluridine (FTD), known as main component of TAS-102, is beginning to be applied as anti-tumor agent due to the highly efficacious antitumor potency although there is little to distinguish FTD structure from thymidine structure. TAS-102 has first been used in Japan in clinical therapy as an oral agent. Some experimental results hypothesized that FTD pharmacological antitumor effect can be arisen by inhibition of thymidylate synthase and incorporation of FTD itself into DNA. One of them is the thermal denaturation experiments for DNA duplexes of containing some FTD or not, performed by J. C. Markley et al. Their experiments have shown that the DNA duplexes containing FTD are slightly less stable, with a melting temperature about three degrees lower than not containing duplexes. However, the change of thermodynamic structure and inter-nucleobase interaction changes are not yet known. In this presentation, we have performed molecular dynamics (MD) simulations and ab initio molecular orbital (MO) calculations to analyze the differences of thermodynamics structure and inter-nucleobase interaction between containing and not containing FTD. From these results, we sought to qualitatively understand the effects of FTD. At the first step, we have estimated the stabilization structures of same two DNA duplexes (containing FTD and not) used by J. C. Markley, with energy minimization. Then, a large differences were shown between these structures. The hydrogen bond breaking is observed between FTD and complementary Adenine base while the not containing DNA duplex keeps having a stabilized structure. The behavior means that the essential difference of intra-DNA interactions was arisen. At the second step, MD simulations were performed to analyze the distribution of distances between FTD and complementary base (i.e. thermally available conformations). With some conformations from MD sampling, the MO calculations were performed to discuss the difference of intra-base interactions. From our results, we found that thermodynamic conformational change of DNA duplex containing FTD occurs even if it is in internal body temperature, and the break hydrogen bonding between FTD and paired base was observed more frequently. In addition, strong interactions between FTD and nearby π-conjugate base were observed. These behaviors might be one of the factor of inducing unstabilization in DNA duplexes. Citation Format: Jun Koseki, Kenta Tsunekuni, Masamitsu Konno, Naohiro Nishida, Koichi Kawamoto, Yuichiro Doki, Masaki Mori, Hideshi Ishii. Thermodynamic and molecular orbital analysis of the effects caused by incorporation of novel anti-tumor agent Trifluridine to DNA. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 2706.