Matherly L H, Barlowe C K, Phillips V M, Goldman I D
J Biol Chem. 1987 Jan 15;262(2):710-7.
This report describes studies designed to evaluate possible inhibitory effects of diaminoantifolates on folate-dependent biosynthetic enzymes in intact L1210 leukemia cells. A novel approach is described which involves an assessment of the metabolism of and biosynthetic flux of the one-carbon moiety from (6S)5-formyltetrahydrofolate in folate-depleted cells. Pretreatment with methotrexate (10 microM), resulting in the formation of methotrexate polyglutamates, or continuous incubation with trimetrexate (1 microM) inhibited growth of folate-depleted L1210 cells in the presence of folic acid or 5-formyltetrahydrolate. In both control and drug-treated cells, double-labeled (6S)-5-[14C]formyl[3H]tetrahydrofolate was rapidly metabolized with the loss of the [14C]formyl group. Under all conditions, the predominant metabolite was 10-formyl[3H]tetrahydrofolate, detectable both intracellularly and extracellularly. In drug-treated cells, there was a remarkably small decrease in the level of 10-formyl[3H]tetrahydrofolate (approximately 30%) and a 10-fold rise in the level of [3H]dihydrofolate to less than 20% of the total folate pool. The incorporation of [14C]formyl group from 5-[14C]formyltetrahydrofolate into thymidylate, serine, and methionine was unaffected by the presence of 1 microM trimetrexate, consistent with the generation of sufficient 5,10-[14C]methylenetetrahydrofolate to drive these reactions. Similarly, the presence of methotrexate polyglutamates had no effect at the level of amino acid synthesis; however, carbon transfer into thymidylate was markedly inhibited. Even though 10-formyltetrahydrofolate was readily formed from 5-formyltetrahydrofolate in this model, the net incorporation of 14C from 5-[14C]formyltetrahydrofolate into purine nucleotides was inhibited by both methotrexate and trimetrexate treatments. Similar findings were obtained when [14C]glycine incorporation into purine nucleotides was monitored in cells incubated with unlabeled 5-formyltetrahydrofolate. Finally, in antifolate-treated cells incubated with unlabeled 5-formyl-tetrahydrofolate, transfer of 14C from [14C]formate or [14C]serine into biosynthetic products or incorporation of [3H]deoxyuridine into nucleic acids was potently inhibited. These results suggest that insufficient levels of tetrahydrofolate and 5, 10-methylenetetrahydrofolate were formed to drive these reactions despite the presence of high levels of 10-formyltetrahydrofolate.(ABSTRACT TRUNCATED AT 400 WORDS)
本报告描述了旨在评估二氨基抗叶酸剂对完整L1210白血病细胞中叶酸依赖性生物合成酶可能的抑制作用的研究。描述了一种新方法,该方法涉及评估叶酸缺乏细胞中(6S)5-甲酰四氢叶酸中一碳部分的代谢和生物合成通量。用甲氨蝶呤(10微摩尔)预处理导致甲氨蝶呤多聚谷氨酸的形成,或与三甲曲沙(1微摩尔)持续孵育,在叶酸或5-甲酰四氢叶酸存在下抑制叶酸缺乏的L1210细胞的生长。在对照细胞和药物处理的细胞中,双标记的(6S)-5-[14C]甲酰基[3H]四氢叶酸都迅速代谢,[14C]甲酰基丢失。在所有条件下,主要代谢产物是10-甲酰基[3H]四氢叶酸,在细胞内和细胞外均可检测到。在药物处理的细胞中,10-甲酰基[3H]四氢叶酸水平显著小幅下降(约30%),[3H]二氢叶酸水平上升10倍,至总叶酸池的不到20%。5-[14C]甲酰四氢叶酸中[14C]甲酰基掺入胸苷酸、丝氨酸和甲硫氨酸不受1微摩尔三甲曲沙存在的影响,这与产生足够的5,10-[14C]亚甲基四氢叶酸以驱动这些反应一致。同样,甲氨蝶呤多聚谷氨酸的存在在氨基酸合成水平上没有影响;然而,碳向胸苷酸的转移受到明显抑制。尽管在该模型中10-甲酰四氢叶酸很容易从5-甲酰四氢叶酸形成,但甲氨蝶呤和三甲曲沙处理均抑制了5-[14C]甲酰四氢叶酸中14C向嘌呤核苷酸的净掺入。当在与未标记的5-甲酰四氢叶酸孵育的细胞中监测[14C]甘氨酸掺入嘌呤核苷酸时,也获得了类似的结果。最后,在用未标记的5-甲酰四氢叶酸孵育的抗叶酸处理的细胞中,[14C]甲酸或[14C]丝氨酸中的14C向生物合成产物的转移或[3H]脱氧尿苷掺入核酸受到有效抑制。这些结果表明,尽管存在高水平的10-甲酰四氢叶酸,但形成的四氢叶酸和5,10-亚甲基四氢叶酸水平不足以驱动这些反应。(摘要截短至400字)
