紫杉醇和浆果赤霉素III衍生物的结构与其对哺乳动物脑微管和绒泡菌变形虫微管解聚的体外作用之间的关系。
Relationships between the structures of taxol and baccatine III derivatives and their in vitro action on the disassembly of mammalian brain and Physarum amoebal microtubules.
作者信息
Lataste H, Senilh V, Wright M, Guénard D, Potier P
出版信息
Proc Natl Acad Sci U S A. 1984 Jul;81(13):4090-4. doi: 10.1073/pnas.81.13.4090.
Abstract
The in vitro disassembly of microtubules from mammalian brain and Physarum is inhibited by various derivatives of taxol and baccatine III. Structure-activity relationships of the taxol derivatives were identical for both mammalian brain and Physarum microtubules. This observation suggests that the site of action of taxol has been preserved during the evolution of these two different eukaryotic lines. The substituent at C-13 of taxol was required to prevent disassembly of brain microtubules with or without microtubule-associated proteins. In contrast, both taxol and baccatine III prevented the disassembly of Physarum microtubules to the same extent, showing that the substituent at C-13 was not required in the interaction with Physarum tubulin. The different effects of baccatine III and taxol derivatives indicate that measuring the disassembly of microtubules from different organisms could be a useful parameter in the search for derivatives exhibiting antiparasitic activity.
摘要
来自哺乳动物大脑和绒泡菌的微管在体外的解聚受到紫杉醇和巴卡亭III的各种衍生物的抑制。紫杉醇衍生物的构效关系对于哺乳动物大脑微管和绒泡菌微管来说是相同的。这一观察结果表明,在这两种不同的真核生物系的进化过程中,紫杉醇的作用位点得以保留。紫杉醇C-13位的取代基对于防止有或无微管相关蛋白时大脑微管的解聚是必需的。相比之下,紫杉醇和巴卡亭III在相同程度上阻止了绒泡菌微管的解聚,表明在与绒泡菌微管蛋白的相互作用中不需要C-13位的取代基。巴卡亭III和紫杉醇衍生物的不同作用表明,测量来自不同生物体的微管解聚情况可能是寻找具有抗寄生虫活性衍生物的一个有用参数。
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