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来自I4的阴离子脂肽作为有效的抗高血压药物:生产、表征和鉴定。

Anionic lipopeptides from I4 as effective antihypertensive agents: Production, characterization, and identification.

作者信息

Ghazala Imen, Bouassida Mouna, Krichen Fatma, Manuel Benito José, Ellouz-Chaabouni Semia, Haddar Anissa

机构信息

Laboratory of Plant Improvement and Valorization of Agricultural Resources (LR16ES20), National School of Engineering Sfax University Sfax Tunisia.

Enzyme Bioconversion Unit (UR13ES74), National School of Engineering Sfax University Sfax Tunisia.

出版信息

Eng Life Sci. 2017 Sep 11;17(12):1244-1253. doi: 10.1002/elsc.201700020. eCollection 2017 Dec.

DOI:10.1002/elsc.201700020
PMID:32624752
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6999559/
Abstract

A new isolated strain I4 was found as producer of biosurfactants by different screening methods, such as parafilm M test, hemolytic activity, oil displacement test, emulsification index, surface tension, and lipase production assay. Enhanced biosurfactants production was obtained using glucose and glutamic acid as carbon and nitrogen sources, respectively. The optimal production of the biosurfactants was obtained by using a C/N ratio of 17, pH of 7.0, and temperature of 37°C. The surface tension was reduced to 29 mN/m and the emulsification index E24 of 62% was achieved after 72 h of culture. The purified biosurfactants showed stability with regard to surface tension reduction and emulsification in a wide range of temperatures (4-120°C), pH (4-10), and salinity (2-12% of NaCl). The thin-layer chromatography showed that the produced biosurfactants were lipopeptides. The biosurfactants were characterized as a group of anionic lipopeptides with zeta potential measurement. Chromatographic characterization using HPLC revealed that I4 lipopeptides contained numerous isoforms and surfactin was the major component. Moreover, the I4 lipopeptides showed interesting angiotensin-converting enzyme-inhibitory activity.

摘要

通过不同的筛选方法,如石蜡膜M试验、溶血活性、油置换试验、乳化指数、表面张力和脂肪酶产生测定,发现了一种新的分离菌株I4,它是生物表面活性剂的产生菌。分别使用葡萄糖和谷氨酸作为碳源和氮源,可提高生物表面活性剂的产量。通过使用碳氮比为17、pH为7.0和温度为37°C,可实现生物表面活性剂的最佳产量。培养72小时后,表面张力降至29 mN/m,乳化指数E24达到62%。纯化后的生物表面活性剂在广泛的温度(4-120°C)、pH(4-10)和盐度(2-12%的NaCl)范围内,在降低表面张力和乳化方面表现出稳定性。薄层色谱显示所产生的生物表面活性剂为脂肽。通过ζ电位测量将生物表面活性剂表征为一组阴离子脂肽。使用HPLC进行的色谱表征表明,I4脂肽包含多种异构体,且表面活性素是主要成分。此外,I4脂肽表现出有趣的血管紧张素转换酶抑制活性。

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