Asano N, Kizu H, Oseki K, Tomioka E, Matsui K, Okamoto M, Baba M
Faculty of Pharmaceutical Sciences, Hokuriku University, Kanazawa, Japan.
J Med Chem. 1995 Jun 23;38(13):2349-56. doi: 10.1021/jm00013a012.
The conformations of nitrogen-in-the-ring sugars and their N-alkyl derivatives were studied from 1H NMR analyses, mainly using 3J(H,H) coupling constants and quantitative NOE experiments. No significant difference was seen in the ring conformation of 1-deoxynojirimycin (1), N-methyl-1-deoxynojirimycin (2), and N-butyl-1-deoxynojirimycin (3). However, it was shown that the C6 OH group in 1 is predominantly equatorial to the piperidine ring, while that in 2 or 3 is predominantly axial, and its N-alkyl group is oriented equatorially. In the furanose analogues 1,4-dideoxy-1,4-imino-D-arabinitol (4) and its N-methyl (5) and N-butyl (6) derivatives, the five-membered ring conformation differed significantly by the presence or absence of the N-substituted group and the length of the N-alkyl chain. Compound 3 reduced its inhibitory effect on almost all glycosidases, resulting in an extremely specific inhibitor for processing alpha-glucosidase I since N-alkylation of 1 is known to enhance both the potency and specificity of this enzyme in vitro and in vivo. This preferred (C6 OH axial) conformation in 2 and 3 appears to be responsible for their strong alpha-glucosidase I activity. Compound 4 is a good inhibitor of intestinal alpha-glucohydrolases, alpha-glucosidase II, and Golgi alpha-mannosidases I and II, but its N-alkyl derivatives 5 and 6 markedly decreased inhibitory potential for all enzymes tested. In the case of 2,5-dideoxy-2,5-imino-D-mannitol (DMDP, 7), which is a potent beta-galactosidase inhibitor, its N-methyl (8) and N-butyl (9) derivatives completely lost potency toward beta-galactosidase as well. N-Alkylation of compounds 4 and 7, known well as potent yeast alpha-glucosidase inhibitors, resulted in a serious loss of inhibitory activity toward yeast alpha-glucohydrolases. Activity of these nine analogues against HIV-1 replication was determined, based on the inhibition of virus-induced cytopathogenicity in MT-4 and MOLT-4 cells. Compounds 2 and 3, which are better inhibitors of alpha-glucosidase I than 1, proved active with EC50 values of 69 and 49 micrograms/mL in MT-4 cells and 100 and 37 micrograms/mL in MOLT-4 cells, respectively, while none of the furanose analogues exhibited any inhibitory effects on HIV-1. The change in potency and specificity of bioactivity by N-alkylation of nitrogen-in-the-ring sugars appears to be correlated with their conformational change.
通过¹H NMR分析,主要利用³J(H,H)耦合常数和定量NOE实验,研究了环氮糖及其N-烷基衍生物的构象。1-脱氧野尻霉素(1)、N-甲基-1-脱氧野尻霉素(2)和N-丁基-1-脱氧野尻霉素(3)的环构象没有明显差异。然而,结果表明,1中的C6 OH基团主要位于哌啶环的平伏键位置,而2或3中的C6 OH基团主要位于直立键位置,且其N-烷基基团取向于平伏键。在呋喃糖类似物1,4-二脱氧-1,4-亚氨基-D-阿拉伯糖醇(4)及其N-甲基(5)和N-丁基(6)衍生物中,五元环构象因N-取代基的存在与否以及N-烷基链的长度而有显著差异。化合物3几乎降低了对所有糖苷酶的抑制作用,成为加工α-葡糖苷酶I的极具特异性的抑制剂,因为已知1的N-烷基化可在体外和体内增强该酶的效力和特异性。2和3中这种优选的(C6 OH直立键)构象似乎是它们具有强α-葡糖苷酶I活性的原因。化合物4是肠道α-葡糖苷水解酶、α-葡糖苷酶II以及高尔基体α-甘露糖苷酶I和II的良好抑制剂,但其N-烷基衍生物5和6对所有测试酶的抑制潜力显著降低。对于作为有效的β-半乳糖苷酶抑制剂的2,5-二脱氧-2,5-亚氨基-D-甘露糖醇(DMDP,7),其N-甲基(8)和N-丁基(9)衍生物对β-半乳糖苷酶也完全失去了效力。作为有效的酵母α-葡糖苷酶抑制剂而广为人知的化合物4和7的N-烷基化,导致对酵母α-葡糖苷水解酶的抑制活性严重丧失。基于对MT-4和MOLT-4细胞中病毒诱导的细胞病变效应的抑制作用,测定了这九种类似物对HIV-1复制的活性。作为比1更好的α-葡糖苷酶I抑制剂的化合物2和3,在MT-4细胞中的EC50值分别为69和49微克/毫升,在MOLT-4细胞中的EC50值分别为100和37微克/毫升,表现出活性,而呋喃糖类似物均未对HIV-1表现出任何抑制作用。环氮糖的N-烷基化导致的生物活性效力和特异性的变化似乎与其构象变化相关。
