Irinotecan overcomes the resistance to 5-fluorouracil in human colon cancer xenografts by down-regulation of intratumoral thymidylate synthase.

To clarify the molecular interaction of irinotecan (CPT-11) and oxaliplatin (l-OHP) in combination with 5-fluorouracil (5-FU), the antitumor effects of CPT-11 and l-OHP combined with the oral 5-FU prodrug, S-1 composed by tegafur, gimeracil and potassium oteracil, were investigated on human colon cancer KM12C xenografts sensitive or resistant to 5-FU in nude mice. In parental KM12C tumor xenografts, combined treatment of CPT-11 with oral S-1 significantly augmented the antitumor activity compared with those of CPT-11 and S-1 alone. Interestingly, combined therapy of CPT-11 with S-1 was markedly effective with almost 90% of inhibition of tumor growth on 5-FU-resistant tumors (KM12C/ 5-FU), and its potency likely corresponded to that in parental tumors. In contrast, combined administration of l-OHP with S-1 did not shown an effect on KM12C/5-FU tumor xenografts. To investigate why only CPT-11 potentiated the anti-tumor activity in combination with 5-FU pro-drugs against 5-FU-resistant colon tumors, the activities or expression levels of thymidylate synthase (TS), ribonucleotide reductase (RNR) and other enzymes in 5-FU-metabolism in both tumors were measured following administration of CPT-11 and/or l-OHP. CPT-11, but not l-OHP, induced a decrease in activities and protein levels of TS and an increase in those of RNR in KM12C/5-FU tumors only, which was likely related to decreased expressions of several proteins in G1/S phase of the cells including CDK4, pRB, and E2F1 in these tumors. These findings suggest that CPT-11, but not l-OHP, would overcome the resistance to 5-FU in combination with 5-FU pro-drugs on 5-FU-resistant colon tumors.

Potentiation of the antitumor activity of alpha, alpha, alpha-trifluorothymidine by the co-administration of an inhibitor of thymidine phosphorylase at a suitable molar ratio in vivo.

Trifluorothymidine (FTD) is a thymidine analog that exhibits an antitumor activity through its inhibition of thymidylate synthase and its incorporation into DNA. However, FTD is rapidly hydrolyzed to an inactive form by thymidine phosphorylase (TP). We attempted to augment the antitumor activity of FTD by combining it with a potent and reversible inhibitor of TP, 5-chloro-6-(2-imino-propyrrolidin-1-yl) methyl-2, 4 (1H, 3H)-pyrimidinedione hydrochloride (TPI) in human tumor xenografts with a low sensitivity to 5-fluorouracil. The optimum ratio of TPI to FTD was determined by measuring the maximum plasma level of FTD after oral administration and the antitumor effect of FTD on human tumor xenografts in mice. When > 0.5 M of TPI and 1 M of FTD (10 mg/kg) were co-administered, the plasma FTD levels in mice and monkeys were elevated, almost reaching a maximal and constant value of 20-30 microg/ml and 15 microg/ml, respectively. When human gastrointestinal cancer cell lines (DLD-1, CO-3 and AZ521) were xenografted into nude mice, the antitumor activity of FTD was augmented by the co-administration of TPI, compared to that of FTD alone, and the ED50 value, used to indicate the antitumor effect, reached a maximum value (about 25, 20, and 10 mg/kg in the DLD-1, CO-3, and AZ521 tumors, respectively) when > 0.5 M of TPI was combined with 1 M of FTD. The oral administration of TPI markedly improved the FTD-induced toxicity, as evaluated by the decrease in the body weight of the mice. These results suggested that the optimum ratio of FTD to TPI was 1:0.5 M, enabling a high antitumor activity and a low toxicity. We further evaluated whether TPI inhibits TP-induced angiogenesis in a gelatin-sponge mouse model, based on the finding that TP is identical to platelet-derived endothelial cell growth factor. Ten and 30 mg/kg administration of TPI significantly inhibited TP-induced neovascularization in a dose-dependent manner in a mouse model. The above results suggest that the combination of TPI and an antitumor nucleoside, FTD, not only enhances the antitumor efficacy and decreases the toxicity of FTD, but also suppresses TP-induced angiogenesis.

Correlations between antitumor activities of fluoropyrimidines and DPD activity in lung tumor xenografts.

The purposes of this study were to evaluate the antitumor activity of S-1 (1 M tegafur, 0.4 M 5-chloro-2,4-dihydroxypyridine and 1 M potassium oxonate) on human lung tumor xenografts, as compared with other fluoro-pyrimidines, and to investigate the relationships between fluoropyrimidine antitumor activities and four distinct enzymatic activities involved in the phosphorylation and degradation pathways of 5-fluorouracil (5-FU) metabolism. S-1, UFT (1 M tegafur-4 M uracil), 5'-deoxy-5-fluorouridine (5'-DFUR), capecitabine and 5-FU were administered for 14 consecutive days to nude mice bearing lung tumor xenografts. S-1 showed stronger tumor growth inhibition in four of the seven tumors than the other drugs. Cluster analysis, on the basis of antitumor activity, indicated that S-1/UFT and 5'-DFUR/capecitabine/5-FU could be classified into another group. We investigated tumor thymidylate synthase content, dihydropyrimidine dehydrogenase (DPD) activity, thymidine phosphorylase (TP) activity and orotate phosphoribosyl transferase activity in seven human lung tumor xenografts and performed regression analyses for the antitumor activities of fluoropyrimidines. There were inverse correlations between antitumor and DPD activities for 5'-DFUR (r=-0.79, P=0.034), capecitabine (r=-0.56, P=0.19) and 5-FU (r=-0.86, P=0.013). However, no such correlations were observed for S-1 and UFT. These findings suggest that S-1 containing a potent DPD inhibitor may have an antitumor effect on lung tumors, with high basal DPD activity, superior to those of other fluoropyrimidines.

A novel combination antimetabolite, TAS-102, exhibits antitumor activity in FU-resistant human cancer cells through a mechanism involving FTD incorporation in DNA.

TAS-102 is a new antimetabolite agent composed of a alpha, alpha, alpha-trifluorothymidine (FTD; 1 M) and thymidine phosphorylase inhibitor (TPI; 0.5 M). Here, we investigated the antitumor effect and mechanism of TAS-102 against 5-FU, or FdUrd, resistant human cancer cell lines. The respective tumor growth inhibition rate of orally administered FTD against 5-FU-resistant NUGC-3 was about 70% at a dose level of 200 mg/kg/day; this value was comparable to that against the parental NUGC-3. On the other hand, the tumor inhibition rates of 5-FU, FdUrd, and TS-1 against 5-FU-resistant NUGC-3 were lower than those against parental NUGC-3. Similar observations were made in an FdUrd-resistant human colorectal cancer cell line (DLD-1). TAS-102 was also effective in 5-FU-less sensitive human pancreatic cancer cell lines (PAN-12 and BxPC-3) and human esophagus cancer (T.T.) when compared with 5-FU or UFT. Our hypothesis was that a relatively short and high dosage of TAS-102 results in an additional mechanism of FTD incorporation into DNA other than thymidylate synthase (TS) inhibition. We then examined the effects of FTD on DNA at the cellular level. After treatment with FTD or FdUrd, the DNA fragmentation pattern was examined using filter elution and in situ nick translation. Treatment with FTD for 2 h resulted in marked DNA fragmentation. When the tumor cells were treated with FTD for 72 h or with FdUrd for 2 or 72 h, only a small amount of DNA fragmentation was observed, and the appearance of the tumor cells did not differ markedly from that of untreated cells. Moreover, the DNA fragmentation rate in the TAS-102 treatment group was significantly higher than that in the control group in vivo. These results suggest that when tumor cells are exposed to high concentrations of FTD for short periods of time, FTD manifests its antitumor activity primarily through the induction of DNA fragmentation after FTD incorporation into the DNA. We conclude that TAS-102 is expected to manifest antitumor effects against 5-FU-resistant tumors that are similar to those exerted in 5-FU-sensitive tumors.

Thymidine kinase and thymidine phosphorylase level as the main predictive parameter for sensitivity to TAS-102 in a mouse model.

TAS-102 is a new oral anti-cancer drug preparation, composed of a 1:0.5 mixture (on a molar basis) of alpha,alpha,alpha-trifluorothymidine (FTD) and 5-chloro-6-[1-(2-iminopyrrolidinyl)methyl]-2,4(1H,3H)-pyrimidinedione hydrochloride (TPI). TAS-102 currently undergoing clinical trials, has been demonstrated to have at least two mechanisms, inhibition of TS and incorporation into DNA. We hypothesized that the thymidine metabolism enzyme may be a crucial factor that affects the antitumor activity of TAS-102. In the present study, we measured the enzyme activity of thymidine kinase (TK), thymidine phosphorylase (TP) and thymidilate synthase (TS) in human cancer xenografts to investigate the contribution of these enzymes to the sensitivity of TAS-102. Antitumor activity of TAS-102 appears to be associated with TK, tumor growth and TS. However, the most related factors in this study were the TK and TP ratio. There was a significant correlation (p=0.04) between tumor growth inhibition and this ratio. These results suggested that the activation and degradation pattern of FTD plays an important role in the efficacy of TAS-102 and that it is possible to use the TK/TP ratio to predict response to TAS-102 therapy. We also studied the influence of TPI on the capacity of exogenous dThd to reverse FTD-dependent growth inhibition. Thymidine (dThd) levels rescued the effect of FTD in vitro and significantly increased in serum after administration of TAS-102 or TPI alone but not FTD alone. This may suggest the possibility of a decrease in antitumor effect. However, our study indicated that the therapeutic index was clearly increased by FTD combined with TPI, compared with FTD alone, suggesting FTD-induced toxicity to sensitive host tissue can be selectively reversed with dThd. In conclusion, TK and TPI effects on TP play important roles in the cytotoxic action of TAS-102, and it is possible to use the TK/TP ratio to predict more precisely individual resistance or sensitivity.

An optimal dosing schedule for a novel combination antimetabolite, TAS-102, based on its intracellular metabolism and its incorporation into DNA.

TAS-102 is a combination drug consisting of alpha,alpha,alpha-trifluorothymidine (FTD) and thymidine phosphorylase inhibitor (TPI). FTD is converted to F3TMP by thymidine kinase and inhibits the thymidylate synthetase (TS) activity by binding to TS. In addition, FTD triphosphate form, F3TTP is incorporated into DNA, which leads to cytocidal effects. Therefore, the incorporation of FTD into DNA is expected to be an important factor, discriminating it from 5-FU showing TS inhibitory activity as their main mechanism of action. To assess a clinically more effective regimen protocol, the intracellular metabolism and the incorporation of FTD into DNA were investigated using human cancer cell lines in vitro and in vivo. FTD was incorporated into DNA in a time-dependent manner, but not in a concentration-dependent manner. FTD was the most efficiently incorporated into DNA after treatment with a several-micro molar level of FTD for around 8 h. The intracellular F3TTP was rapidly eliminated from tumor cells, as soon as FTD was washed out from the culture medium, whereas the FTD incorporated into DNA was retained by 80% or more even at 24 h after a washing-out procedure. When TAS-102 was administered into tumor-bearing mice once daily or three times daily at 3-h intervals at a dose of 150 mg/kg/day for one or 3 consecutive days, incorporation of FTD into tumor DNA by divided dosing significantly higher than that of single dosing. Based on our findings, the antitumor effects of TAS-102 against 3 different human cancer cell xenografts into mice were examined. The divided daily dosing resulted in enhancement of the antitumor effects of TAS-102 without any additional side effects. It is concluded that multiple daily dosing may result in better clinical benefits of TAS-102, when compared with single daily dosing and TAS-102 is a promising candidate for not only FU-sensitive but also FU-resistant cancer patients.

[Antimetastatic and antitumor effects of fluoropyrimidines alone and combined with taxanes in a murine model of breast cancer metastatic to the lung].

To evaluate the antitumor efficacy against metastatic breast cancer of fluoropyrimidines alone and combined with other chemotherapeutic agents, we developed a murine model of breast cancer metastatic to the lung by orthotopically implanting MDA-MB-435S breast tumors into mice. MDA tumor cells greatly metastasized to lung tissue only after the orthotopically implanted tumors were surgically removed. Measurement of the expression of enzymes involved in 5-FU metabolism showed significantly higher activity of dihydropyrimidine dehydrogenase (DPD) and lower activity of thymidylate synthase (TS) in the MDA metastases than in the orthotopically implanted tumors. Based on the enzymatic properties of metastatic tumors, the minimum toxic doses of UFT (17.5 mg/kg/day) as a DPD-inhibitory fluoropyrimidine (DIF), and of 5'-DFUR (120 mg/kg/day) as a non-DIF, were orally administered to mice with pulmonary metastasis of the breast tumor. The results showed that UFT significantly inhibited the growth of pulmonary metastases of the breast tumors, but 5'-DFUR did not. UFT seemed to inhibit the growth of the pulmonary metastases of the breast tumors in combination with paclitaxel (50 mg/kg) more than in combination with 5'-DFUR, although the antitumor efficacy of neither combination was significantly different from that of paclitaxel alone. These results suggest that combination of DIF with other chemotherapeutic drugs, such as taxanes, is required to attain high antimetastatic and antitumor efficacy against breast tumor metastases, based on the molecular characteristics of the metastatic tumors.