Tiazofurin down-regulates expression of c-Ki-ras oncogene in a leukemic patient.

The increased activity in cancer cells of inosine 5'-monophosphate dehydrogenase (IMP DH, EC 1.1.1.205), the rate-limiting enzyme of de novo GTP biosynthesis, was suggested as a sensitive target for chemotherapy. Tiazofurin (NSC 286193), through its conversion to the active metabolite, thiazole-4-carboxamide adenine dinucleotide (TAD), is a strong inhibitor of IMP DH. In our clinical trial, tiazofurin caused return to the chronic phase in patients with chronic granulocytic leukemia in blast crisis (Tricot, G.; Jayaram, H.N.; Weber, G.; Hoffman, R. Tiazofurin: Biological effects and clinical uses. Int. J. Cell Cloning 8:161-170; 1990). In K562 human leukemic cells, tiazofurin down-regulated the expression of c-Ki-ras and c-myc oncogenes, which was followed by induced differentiation. We now report down-regulation by tiazofurin of the c-Ki-ras oncogene in a patient with chronic granulocytic leukemia in blast crisis. A single tiazofurin infusion (2,200 mg/m2) on days one and two decreased IMP dehydrogenase activity (the apparent t1/2 was 30 min), GTP concentration (the apparent t1/2 was 6 hr), and expression of ras (the apparent t1/2 was 8 hr) and c-myc (the apparent t1/2 was 38.5 hr) oncogenes in the leukemic cells. No further tiazofurin was given, because on days three and four the chemotherapeutic impact became evident in a tumor-lysis syndrome and the blast cells were cleared from the periphery by day five. The decrease in IMP DH activity, GTP concentration, and expression of c-Ki-ras oncogene were early markers of the successful chemotherapeutic impact of tiazofurin in a patient with chronic granulocytic leukemia in blast crisis.

Regulation of de novo and salvage pathways in chemotherapy.

An overview was presented of our approach of inhibition of de novo and salvage pathways in pyrimidine and purine metabolism. 1. Combination of acivicin, an inhibitor of de novo biosynthesis, and dipyridamole, a transport inhibitor, provided synergistic cytotoxicity in hepatoma and colon carcinoma cells. 2. AZT, a competitive inhibitor of the salvage enzyme, thymidine kinase, and 5-FU or MTX provided synergistic cytotoxicity in hepatoma 3924A. In human colon carcinoma HT-29 cells AZT and methotrexate yielded synergistic cytotoxicity and thymidine and hypoxanthine together provided protection from the action of these drugs. 3. These observations are significant because in rat hepatoma 3924A and in human cell lines HT-29, HL-60 and K562 thymidine kinase activity was 16- to 67-fold higher than that of dTMP synthase. Therefore, inhibition of dTMP synthase activity alone may provide poor responses because the salvage pathways can circumvent this block. 4. In leukemic patients treated with tiazofurin, an inhibitor of IMP dehydrogenase, the rate-limiting enzyme of GTP biosynthesis, and with allopurinol, which inhibits GPRT activity through raising plasma hypoxanthine levels, synergistic therapeutic results were obtained. The responses in sensitive patients entailed a decrease in IMP dehydrogenase activity and GTP concentration in leukemic cells and down-regulation of the ras and myc oncogenes. The down-regulation of the ras oncogene by tiazofurin through the decrease of GTP concentration has now been shown in K562, HL-60 and hepatoma cells and in patients with chronic granulocytic leukemia in blast crisis. Tiazofurin may be useful in studies on selective depression of the expression of the ras oncogene. 5. In 27 consecutive patients 50% responded positively to tiazofurin treatment. From this group, 10 out of 12 patients (83%) with chronic granulocytic leukemia in blast crisis responded to tiazofurin treatment.

Tiazofurin action in leukemia: evidence for down-regulation of oncogenes and synergism with retinoic acid.

New light was thrown on the action of tiazofurin in the treatment of end-stage leukemic patients and in leukemic cells in tissue culture. 1. In a population of 21 consecutive patients 50% responded to tiazofurin treatment, confirming the usefulness of this therapy in end-stage leukemia. 2. In leukemic patients treated with tiazofurin and allopurinol reciprocal action was manifested in the increase in hypoxanthine and the decrease in uric acid concentrations in the plasma. On discontinuation of allopurinol, hypoxanthine levels steeply declined but uric acid concentration increased slowly, taking days to reach pretreatment level. 3. With a new and sensitive method the concentration of the active metabolite of tiazofurin, TAD, was measured in the mononuclear cells of tiazofurin-treated patients. Approximately 5 to 13% of the plasma tiazofurin level was observed as TAD in the mononuclear cells. This TAD concentration was sufficient to account for the inhibition of IMP DH in these cells. 4. Tiazofurin or retinoic acid caused differentiation of HL-60 leukemic cells and inhibition of cell proliferation. 5. By treating leukemic cells incubated with tiazofurin or retinoic acid also with guanosine it was elucidated that the mechanism of the two drugs differed since only the tiazofurin effects were counteracted by guanosine. 6. Tiazofurin and retinoic acid together in HL-60 cells provided synergistic impact on differentiation and cytotoxicity. 7. Tiazofurin resulted in down-regulation of the expression of ras and myc oncogenes in three systems: K562 human erythroleukemic cells, rat hepatoma 3924A cells and human HL-60 leukemia cells. 8. Because both tiazofurin and retinoic acid are licensed drugs, their potential use in combination chemotherapy may have clinical relevance in the treatment of end-stage leukemia where our earlier studies have demonstrated the usefulness of tiazofurin.

Clinical and molecular impact of inhibition of IMP dehydrogenase activity by tiazofurin.

The impact of tiazofurin on inhibition of IMP dehydrogenase was discussed at the clinical and molecular levels. 1. Evidence was provided for the role of IMP dehydrogenase and guanylates in the expression of the neoplastic program in cancer cells with particular relevance to human leukemic cells. 2. The argument for expecting an impact of tiazofurin in human myelocytic cells was provided. 3. Similarity of the kinetics of human leukemic cell IMP dehydrogenase to the rat hepatoma enzyme was documented. 4. New evidence was provided for the role of salvage in chemotherapy and the function of hypoxanthine in inhibiting guanine salvage. 5. The action of tiazofurin and retinoic acid was reported in HL-60 leukemic cells. 6. The effect of tiazofurin and retinoic acid on proliferation and cytotoxicity was outlined for hepatoma 3924A cells. 7. The effect of guanine on induced differentiation by tiazofurin and retinoic acid was examined. 8. Biochemical basis was provided for the lack of development of resistance in patients treated with tiazofurin. 9. Presumptive evidence was provided that tiazofurin treatment induced differentiation of leukemic cells in the patients. 10. The molecular biology of tiazofurin-induced differentiation in K-562 cells was reviewed with the possible relevance to clinical treatment that tiazofurin might also act through down-regulation of ras oncogene.