Nair M G, Murthy B R, Patil S D, Kisliuk R L, Thorndike J, Gaumont Y, Ferone R, Duch D S, Edelstein M P
Department of Biochemistry, University of South Alabama, Mobile 36688.
J Med Chem. 1989 Jun;32(6):1277-83. doi: 10.1021/jm00126a022.
The Boon-Leigh procedure, involving condensation of a 6-chloro-5-nitropyrimidine (22) with an alpha-amino ketone (20 or 21) followed by reduction of the nitro group, cyclization, and L-glutamylation, led to the formation of 11-deazahomofolate (29) and its 10-methyl derivative (30). The corresponding (6R,S)-5,6,7,8-tetrahydro (4, 5) and 7,8-dihydro (31, 32) derivatives were prepared by catalytic hydrogenation. (6S)-11-Deazatetrahydrohomofolate was prepared from 29 by enzymatic reduction. Compounds 29 and 30 had little effect (IC50 greater than 2 x 10(-5) M) on Lactobacillus casei glycinamide ribonucleotide (GAR) formyltransferase but (6R,S)-11-deazatetrahydrohomofolate (4) is a potent inhibitor of this enzyme (IC50 = 5 x 10(-8) M). It is at least 100 times more inhibitory than 33, the 6S compound, indicating that the 6R component of the mixture having the unnatural configuration at C6 (34) is responsible for the potent inhibition. Compound 4 is a much weaker inhibitor of murine (L1210) and human (MOLT-4) leukemia cell GAR formyltransferases (IC50 greater than 1 x 10(-5) M). (6R,S)-11-Deaza-10-methyltetrahydrohomofolate (5) (IC50 = 1.1 x 10(-5) is 200 times weaker than 4 against L. casei GAR formyltransferase. However, 11-deaza-10-methyldihydrohomofolate (32) is more inhibitory (IC50 = 5.5 x 10(-7) M) than 5 or 30. None of the compounds showed inhibition of L. casei aminoimidazolecarboxamide ribonucleotide (AICAR) formyltransferase, dihydrofolate reductase, or thymidylate synthase. The dihydro derivatives 31 and 32 are 5% as active as dihydrofolate as substrates for L. casei dihydrofolate reductase. Compound 4 showed moderate inhibition of the growth of L. casei, Streptococcus faecium, MOLT-4 cells, and MCF-7 human breast adenocarcinoma cells.
布恩 - 利 procedure,涉及6 - 氯 - 5 - 硝基嘧啶(22)与α - 氨基酮(20或21)缩合,随后硝基还原、环化和L - 谷氨酰化,导致形成11 - 去氮高叶酸(29)及其10 - 甲基衍生物(30)。相应的(6R,S) - 5,6,7,8 - 四氢(4,5)和7,8 - 二氢(31,32)衍生物通过催化氢化制备。(6S) - 11 - 去氮四氢高叶酸由29通过酶促还原制备。化合物29和30对干酪乳杆菌甘氨酰胺核糖核苷酸(GAR)甲酰基转移酶几乎没有影响(IC50大于2×10^(-5) M),但(6R,S) - 11 - 去氮四氢高叶酸(4)是该酶的有效抑制剂(IC50 = 5×10^(-8) M)。它的抑制作用比6S化合物33至少强100倍,表明在C6处具有非天然构型的混合物的6R组分(34)是强效抑制的原因。化合物4对小鼠(L1210)和人(MOLT - 4)白血病细胞GAR甲酰基转移酶的抑制作用弱得多(IC50大于1×10^(-5) M)。(6R,S) - 11 - 去氮 - 10 - 甲基四氢高叶酸(5)(IC50 = 1.1×10^(-5))对干酪乳杆菌GAR甲酰基转移酶的抑制作用比4弱200倍。然而,11 - 去氮 - 10 - 甲基二氢高叶酸(32)比5或30更具抑制性(IC50 = 5.5×10^(-7) M)。这些化合物均未显示对干酪乳杆菌氨基咪唑甲酰胺核糖核苷酸(AICAR)甲酰基转移酶、二氢叶酸还原酶或胸苷酸合酶有抑制作用。二氢衍生物31和32作为干酪乳杆菌二氢叶酸还原酶的底物,其活性仅为二氢叶酸的5%。化合物4对干酪乳杆菌、屎肠球菌、MOLT - 4细胞和MCF - 7人乳腺腺癌细胞的生长有中度抑制作用。
