Enhanced avermectin production by Streptomyces avermitilis ATCC 31267 using high-throughput screening aided by fluorescence-activated cell sorting

Cao, Xiufeng; Luo, Zhengshan; Zeng, Weizhu; Xu, Sha; Zhao, Lingyun; Zhou, Jingwen

doi:10.1007/s00253-017-8658-x

Cited by 31 publications

(22 citation statements)

References 37 publications

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“…Cao et al. established a reliable high‐throughput screening (HTS) strategy integrating fluorescence‐activated cell sorting and random mutagenesis for screening high avermectin titer S. avermitilis mutants. They reported that a high‐titer avermectin producer (G9) was obtained from 5760 mutants after mutagenesis and HTS.…”

Section: Resultsmentioning

confidence: 99%

“…The ZJAV-Y-HS mutants was found to provide the best production, with maximal production of 4632.17 μg/mL of avermectin and other analogue after 240 h. Among the ZJAV-Y-147 and ZJAV-Y-HS mutants and the wild-type strain, the ZJAV-Y-147 mutant was found to provide the best production, yielding maximal production of 4822.23 μg/mL of the B1a component of avermectin as estimated by HPLC-UV. Cao et al [32] established a reliable high-throughput screening (HTS) strategy integrating fluorescence-activated cell sorting and random mutagenesis for screening high avermectin titer S. avermitilis mutants. They reported that a high-titer avermectin producer (G9) was obtained from 5760 mutants after mutagenesis and HTS.…”

Section: Production Of Avermectin B1a and Its Analogs By The Mutants mentioning

confidence: 99%

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Effects of heavy‐ion beam irradiation on avermectin B1a and its analogues production by Streptomyces avermitilis

Wang

Chen

et al. 2018

Engineering in Life Sciences

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The biggest challenge in anabolism research is to improve the stability and safety of microbial metabolite production on an industrial scale. One class of metabolites, avermectins, are produced by Streptomyces avermitilis. In this study, an avermectin B1a‐high‐producing mutant was produced using heavy ion mutagenesis and selected based on LTQ‐MS and HPLC‐UV method. The mutants ZJAV‐Y‐147 and ZJAV‐Y‐HS, obtained after subjecting the spores of S. avermitilis to 70 Gy of 12C6+ heavy ion irradiation, were found to best improve the avermectin B1a production (4822.23 μg/mL and 4632.17 μg/mL, respectively). These two mutants’ yielded of avermectin B1a were 2‐fold high than the original strains. The DNA of the original and mutant strains were analyzed by RAPD technique with four random primers after irradiated with ion beam irradiation. The results show that different high‐titer S. avermitilis strains contain different genetic modifications. In addition, the mutation position, mutation type and sequence context of all mutations of aveC, aveD, aveI, aveR gene in two mutants S.avermitilis were researched, and the production of avermectin B1a and its analogues of wild‐type and mutants were analyzed by fermenting 240 h, which was suggested that the partial base deletion of aveI gene may be the key sites for increasing avermectin B1a production after the 12C6+‐ion irradiation. All these modifications promote increased avermectin biosynthesis, leading to multiple high‐titer S. avermitilis strains. The results demonstrate that this is an effective approach to engineer S. avermitilis as a host for the biological production of commercial analogs.

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Section: Resultsmentioning

confidence: 99%

Section: Production Of Avermectin B1a and Its Analogs By The Mutants mentioning

confidence: 99%

Effects of heavy‐ion beam irradiation on avermectin B1a and its analogues production by Streptomyces avermitilis

Wang

Chen

et al. 2018

Engineering in Life Sciences

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“…周扬等人 [97] 通过活跃链霉菌产生的那西肽对藤黄微球菌具有抑制效果, 根据抑菌圈的大小经高通量筛选获得了那西肽高产菌株. Cao等人 [98] 通过对孢子进行碘化丙锭(PI)和二乙酸荧光素(FDA) 染色, 利用流式细胞仪分选活性孢子, 高通量筛选了阿维菌素高产菌株. Zeng等人 [99] Figure 3 (Color online) The process of microbial high throughput screening 型在菌株之间的传递成为可能 [104] .…”

Section: 体生长情况及其代谢特性如营养缺陷型、耐受性、水解圈、显色圈、抑菌圈等;unclassified

Functional development and performance enhancement of probiotics

Zhang

Chen

2018

Chin. Sci. Bull.

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“…Although ARTP has several outstanding advantages over other conventional methods, including rapid mutation rate and high operational flexibility (Zhang et al, 2014). In order to obtain a desired target, a single ARTP treatment or an iterative ARTP treatment is usually performed (Wang et al, 2010; Zhang et al, 2015; Ren et al, 2017; Cao et al, 2018). Interestingly, in previous studies, ARTP treatment was also combined with other treatments such as single resistance screening (Liang et al, 2015; Ren et al, 2017), or radiation mutagenesis with UV (Zhang et al, 2015) to improve the overall efficiency.…”

Section: Introductionmentioning

confidence: 99%

Combinatorial Effect of ARTP Mutagenesis and Ribosome Engineering on an Industrial Strain of Streptomyces albus S12 for Enhanced Biosynthesis of Salinomycin

Zhang

Mohsin

Dai

et al. 2019

Front. Bioeng. Biotechnol.

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Salinomycin, an important polyketide, has been widely utilized in agriculture to inhibit growth of pathogenic bacteria. In addition, salinomycin has great potential in treatment of cancer cells. Due to inherited characteristics and beneficial potential, its demand is also inclining. Therefore, there is an urgent need to increase the current high demand of salinomycin. In order to obtain a high-yield mutant strain of salinomycin, the present work has developed an efficient breeding process of Streptomyces albus by using atmospheric and room temperature plasma (ARTP) combined with ribosome engineering. In this study, we investigate the presented method as it has the advantage of significantly shortening mutant screening duration by using an agar block diffusion method, as compared to other traditional strain breeding methods. As a result, the obtained mutant Tet30Chl25 with tetracycline and chloramphenicol resistance provided a salinomycin yield of 34,712 mg/L in shake flask culture, which was over 2.0-fold the parental strain S12. In addition, comparative transcriptome analysis of low and high yield mutants, and a parental strain revealed the mechanistic insight of biosynthesis pathways, in which metabolic pathways including butanoate metabolism, starch and sucrose metabolism and glyoxylate metabolism were closely associated with salinomycin biosynthesis. Moreover, we also confirmed that enhanced flux of glyoxylate metabolism via overexpression gene of isocitrate lyase (icl) promoted salinomycin biosynthesis. Based on these results, it has been successfully verified that the overexpression of crotonyl-CoA reductase gene (crr) and transcriptional regulator genes (orf 3 and orf 15), located in salinomycin synthesis gene cluster, is possibly responsible for the increase in salinomycin production in a typical strain Streptomyces albus DSM41398. Conclusively, a tentative regulatory model of ribosome engineering combined with ARTP in S. ablus is proposed to explore the roles of transcriptional regulators and stringent responses in the biosynthesis regulation of salinomycin.

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Enhanced avermectin production by Streptomyces avermitilis ATCC 31267 using high-throughput screening aided by fluorescence-activated cell sorting

Cited by 31 publications

References 37 publications

Effects of heavy‐ion beam irradiation on avermectin B1a and its analogues production by Streptomyces avermitilis

Effects of heavy‐ion beam irradiation on avermectin B1a and its analogues production by Streptomyces avermitilis

Functional development and performance enhancement of probiotics

Combinatorial Effect of ARTP Mutagenesis and Ribosome Engineering on an Industrial Strain of Streptomyces albus S12 for Enhanced Biosynthesis of Salinomycin

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