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胆固醇和麦角固醇与多烯抗生素制霉菌素的竞争性结合。一项荧光研究。

Competitive binding of cholesterol and ergosterol to the polyene antibiotic nystatin. A fluorescence study.

作者信息

Silva Liana, Coutinho Ana, Fedorov Alexander, Prieto Manuel

机构信息

CQFM, Instituto Superior Técnico, Lisbon, Portugal.

出版信息

Biophys J. 2006 May 15;90(10):3625-31. doi: 10.1529/biophysj.105.075408. Epub 2006 Feb 24.

DOI:10.1529/biophysj.105.075408
PMID:16500971
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1440743/
Abstract

Competition studies between cholesterol and ergosterol were carried out to gain insight into the binding interactions between nystatin and these sterols. Lipid vesicles were prepared with mixtures of palmitoyloleoylphosphocholine/ergosterol/cholesterol, and both sterol molar ratio and total content were varied. The inhibitory effect of cholesterol toward the ergosterol ability to induce the formation of long-lived fluorescent antibiotic species was used to detect nystatin-cholesterol interactions. It was found that the key factor controlling nystatin photophysical properties in the ternary lipid mixtures was their ergosterol/cholesterol molar ratio and not their overall sterol content. Moreover, permeabilization studies showed that nystatin was able to form pores in all the mixed vesicles, but the initial rate of pore formation was also dependent on the ergosterol/cholesterol molar ratio. Our data show that ergosterol is displaced by competing cholesterol, indirectly confirming cholesterol's ability to coassemble with nystatin. The distinct spectroscopic properties emphasize the different molecular architecture adopted by nystatin-cholesterol and -ergosterol complexes, and therefore are relevant to understanding the interaction of the antibiotic with membranes.

摘要

开展了胆固醇与麦角固醇之间的竞争研究,以深入了解制霉菌素与这些固醇之间的结合相互作用。用棕榈酰油酰磷脂酰胆碱/麦角固醇/胆固醇的混合物制备脂质囊泡,并改变固醇摩尔比和总含量。利用胆固醇对麦角固醇诱导形成长寿命荧光抗生素物种能力的抑制作用来检测制霉菌素 - 胆固醇相互作用。研究发现,在三元脂质混合物中控制制霉菌素光物理性质的关键因素是它们的麦角固醇/胆固醇摩尔比,而非其总固醇含量。此外,通透化研究表明,制霉菌素能够在所有混合囊泡中形成孔,但孔形成的初始速率也取决于麦角固醇/胆固醇摩尔比。我们的数据表明,竞争性胆固醇会取代麦角固醇,间接证实了胆固醇与制霉菌素共同组装的能力。独特的光谱性质强调了制霉菌素 - 胆固醇和 - 麦角固醇复合物所采用的不同分子结构,因此与理解抗生素与膜的相互作用相关。

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