生物反应器中表面活性素的生产：重点关注磁性纳米颗粒的应用。

Surfactin production in the bioreactor: Emphasis on magnetic nanoparticles application.

作者信息

Modabber Glayol, Sepahi Abbas Akhavan, Yazdian Fatemeh, Rashedi Hamid

机构信息

Department of Microbiology, Faculty of Biological Sciences Islamic Azad University Tehran Iran.

Department of Life Science Engineering, Faculty of New Science and Technologies University of Tehran Tehran Iran.

出版信息

Eng Life Sci. 2020 Jun 9;20(11):466-475. doi: 10.1002/elsc.201900163. eCollection 2020 Nov.

DOI:10.1002/elsc.201900163

PMID:33204233

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7645645/

Abstract

Surfactin is one of the main lipopeptide biosurfactants produced by different species of . This study aims to analyze the effect of starch-coated Fe and Fe nanoparticles on the biomass and biosurfactant production of . Out of 70 soil samples, 20 were isolated and genome sequenced by biochemical methods and 16S rRNA gene. Quantitative and qualitative screening methods were used to isolate and detect biosurfactant production. For the aim of this study, 61 and 63 () were selected. Then, hemolytic activity, biomass amount, surfactant production, and reduction of surface tension in Minimal Salt Medium containing Fe and Fe nanoparticles were examined after 48, 72, and 96 h of culture. Strain 61 was the best bacterium and Fe was the best nanoparticle. The results were compared with the results of non-nanoparticle bioreactor. The results showed the amount of biomass, surfactin, and surface tension decrease, 72 h after growth in 61 strain containing Fe reached the highest values. Surfactin from strain 61 culture in the Fenanoparticle bioreactor after 72 h of growth showed higher production than the same strain culture after 72 h without Fe, if continuing the research, this strain can be commercialized in the future.

摘要

表面活性素是由不同种类的产生的主要脂肽生物表面活性剂之一。本研究旨在分析淀粉包覆的铁和铁纳米颗粒对的生物量和生物表面活性剂产量的影响。在70个土壤样本中，通过生化方法和16S rRNA基因分离出20个并进行基因组测序。采用定量和定性筛选方法分离和检测生物表面活性剂的产生。为了本研究的目的，选择了61个和63个（）。然后，在含有铁和铁纳米颗粒的最低盐培养基中培养48、72和96小时后，检测溶血活性、生物量、表面活性剂产量以及表面张力的降低情况。菌株61是最佳细菌，铁是最佳纳米颗粒。将结果与非纳米颗粒生物反应器的结果进行比较。结果表明，生物量、表面活性素和表面张力的量减少，在含有铁的61菌株中生长72小时后达到最高值。在含有铁纳米颗粒的生物反应器中生长72小时后，菌株61培养物中的表面活性素产量高于不含铁培养72小时后的同一菌株培养物，如果继续进行研究，该菌株未来可实现商业化。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/63dd/7645645/4deac447594e/ELSC-20-466-g003.jpg

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生物反应器中表面活性素的生产：重点关注磁性纳米颗粒的应用。

Surfactin production in the bioreactor: Emphasis on magnetic nanoparticles application.

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