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19. Purification and cloning of lectin that induce cell apoptosis from Allium chinense

Author

Xiao, Xiuqing, He, Hao, Ding, Xuezhi, Yang, Qi, Liu, Xuemei, Liu, Shuang, Rang, Jie, Wang, Ting, Zuo, Mingxing, and Xia, Liqiu

Subjects
Medical research, Medicine, Experimental, Medicine, Botanic -- Research, Apoptosis -- Research, Medicine, Herbal -- Research, Lectins -- Research, Cloning -- Research, Biological sciences, Health, Science and technology
Abstract

ABSTRACT A 8.7 kDa lectin with high agglutin activity was isolated by affinity chromatography and cloned from Allium chinense in this study. For the MTT assay, approximately 60 µg/ml A. [...]

Published
2015
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23. Additional file 1 of A TetR family transcriptional regulator, SP_2854 can affect the butenyl-spinosyn biosynthesis by regulating glucose metabolism in Saccharopolyspora pogona

Author

Rang, Jie, Xia, Ziyuan, Shuai, Ling, Cao, Li, Liu, Yang, Li, Xiaomin, Xie, Jiao, Li, Yunlong, Hu, Shengbiao, Xie, Qingji, and Xia, Liqiu

Abstract

Additional file 1: Table S1. Oligonucleotides used in this study. Table S2. qRT-PCR primers used in this study. Figure S1. Mass spectrum identification of butenyl-spinosyn. (A) Chromatographic peak detection spectrum in 13.0 min. (B) Chromatographic peak detection spectrum of secondary spectrum in 13.0 min. MS identification results showed that (M + H) + ions at m/z = 633.17 (black arrow) contained a rhamnose ion fragment of 189 molecular mass, which was confirmed as a butenyl-spinosyn component spinosyn 6-methyl β. Figure S2. Sporulation observation of the S. pogona-ΔSP_2854 (1), S. pogona::SP_2854 (2), and S. pogona (3) in the BHI, CSM and TSB solid media. The strains were grown on the BHI, CSM and TSB solid media and photographed on days 5.

Published
2022
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24. Screening of new Paenibacillus polymyxa S3 and its disease resistance of grass carp (Ctenopharyngodon idellus).

Author

Yang, Shijia, Jin, Duo, Li, Hui, Jiang, Lingzhi, Cui, Jun, Huang, Weitao, Rang, Jie, Li, YunLong, and Xia, Liqiu

Subjects
CTENOPHARYNGODON idella, AEROMONAS hydrophila, MEDICAL screening, IMMUNOGLOBULIN M, PAENIBACILLUS, WHOLE genome sequencing, FISH pathogens
Abstract

A new strain of Paenibacillus polymyxa S3 with antagonistic effects on 11 major fish pathogens (especially Aeromonas hydrophila), but had no toxicity to grass carp, was screened from the sediment of fishponds. In vivo colonization studies showed that strain S3 could be colonized and distributed in the gill and abdomen of the grass carp. Bioassay results showed that the weight growth rate of grass carp in the strain S3 oral group (16.01%) and strain S3 immersion group (16.44%) was significantly higher than those of the control group (8.61%). At the same time, the activities of ACP, AKP, CAT and GSH‐Px in the serum of grass carp in oral and immersion groups were significantly higher than those of the control group. In addition, the treatment with strain S3 could significantly upregulate the expression of the antioxidant‐related genes and immune‐related genes Keap1, Nrf2, C3, LZM, IgM, TLR‐4 and MyD‐88 in grass carp tissues. The challenge test showed that strain S3 treatment significantly increased the survival rate of grass carp infected with Aeromonas hydrophila. Whole genome sequencing analysis showed that strain S3 had 16 active metabolite gene clusters, indicating that it had abundant gene resources, which provided important support for its development for fish microecological preparations. In summary, a new strain of Paenibacillus polymyxa S3 with antibacterial activity against a variety of fish pathogens was screened in this study and its probiotic function was evaluated, proving its potential value in fisheries. [ABSTRACT FROM AUTHOR]

Published
2023
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25. Comparative Proteomics Reveals the Effect of the Transcriptional Regulator Sp13016 on Butenyl-Spinosyn Biosynthesis in Saccharopolyspora pogona

Author

Tang, Jianli, primary, He, Haocheng, additional, Li, Yunlong, additional, Liu, Zhudong, additional, Xia, Ziyuan, additional, Cao, Li, additional, Zhu, Zirong, additional, Shuai, Ling, additional, Liu, Yang, additional, Wan, Qianqian, additional, Luo, Yuewen, additional, Zhang, Youming, additional, Rang, Jie, additional, and Xia, Liqiu, additional

Published
2021
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26. Flaviolin-Like Gene Cluster Deletion Optimized the Butenyl-Spinosyn Biosynthesis Route in Saccharopolyspora pogona

Author

He, Haocheng, primary, Tang, Jianli, additional, Chen, Jianming, additional, Hu, Jinjuan, additional, Zhu, Zirong, additional, Liu, Yang, additional, Shuai, Ling, additional, Cao, Li, additional, Liu, Zhudong, additional, Xia, Ziyuan, additional, Ding, Xuezhi, additional, Hu, Shengbiao, additional, Zhang, Youming, additional, Rang, Jie, additional, and Xia, Liqiu, additional

Published
2021
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27. Additional file 1 of Bacterioferritin: a key iron storage modulator that affects strain growth and butenyl-spinosyn biosynthesis in Saccharopolyspora pogona

Author

Tang, Jianli, Zhu, Zirong, He, Haocheng, Liu, Zhudong, Xia, Ziyuan, Chen, Jianming, Hu, Jinjuan, Cao, Li, Rang, Jie, Shuai, Ling, Liu, Yang, Sun, Yunjun, Ding, Xuezhi, Hu, Shengbiao, and Xia, Liqiu

Abstract

Additional file 1: Table S1. Strains, plasmids and primers used in this study. Table S2. qRT-PCR primers used in this study. Table S3. Biological insecticidal activity of wt, Δbfr and ::bfr. Figure S1. LC-MS/MS identification of butenyl-spinosyn. Figure S2. Phylogenetic tree analysis of bacterioferritin. Figure S3. Construction and recombination schematic diagram of pKCcas9dO-sgRNA-UHA-DHA and pOJ260-kasOp*-bfr. Figure S4. Identification of Δbfr and ::bfr. Figure S5. Tricine-SDS-PAGE analysis and 1D-LC-MS/MS identification of heterologously expressed protein Bfr. Figure S6. Butenyl-spinosyn yield curve of the wild-type and mutants. Figure S7. Statistics of total protein and differential protein between the wild-type and mutant strains identified in the quantitative proteome. Figure S8. The expression fold change of bus family proteins between bfr mutant strains and wild-type strain. Figure S9. Verification of the transcription levels of iron homeostasis and oxidative stress-related proteins.

Published
2021
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28. Additional file 1 of Effects of acuC on the growth development and spinosad biosynthesis of Saccharopolyspora spinosa

Author

Liu, Zhudong, Xiao, Jie, Tang, Jianli, Liu, Yang, Shuai, Ling, Cao, Li, Xia, Ziyuan, Ding, Xuezhi, Rang, Jie, and Xia, Liqiu

Abstract

Additional file 1: Table S1. Strains and plasmids used in this study. Table S2. Nucleotide sequences of primers. Figure S1. Construction and verification of S. spinosa-ΔacuC. Figure S2. Construction and verification of S. spinosa-acuC. Figure S3. The insecticidal activity of the wild-type and mutant strains on H. armigera. Figure S4. The content of Acetyl-CoA between the wild-type and overexpression strains in 48 h, 96 h and 192 h. Figure S5. The acetate content remained in bacteria between the wild-type and overexpression strains during fermentation. Figure S6. The consumption curve of glucose content in the fermentation medium during the growth process. Figure S7. The SDS-PAGE analysis of whole-cell proteins of the wild-type and mutant strains at 48 h. Figure S8. Comparison of acuC protein sequences among different bacteria.

Published
2021
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33. Additional file 1 of Effect of the TetR family transcriptional regulator Sp1418 on the global metabolic network of Saccharopolyspora pogona

Author

Haocheng He, Shuangqin Yuan, Jinjuan Hu, Jianming Chen, Rang, Jie, Jianli Tang, Zhudong Liu, Ziyuan Xia, Xuezhi Ding, Shengbiao Hu, and Liqiu Xia

Abstract

Additional file 1: Figure S1. Mass spectrum identification of butenyl-spinosyns. MS identification results showed that MS parent ion [M+H]+ = 633 (black arrow) contained 617 (M+H+) (m/z) ion data and a rhamnose ion fragment of 189 molecular mass, which was confirmed as a butenyl-spinosyn component. Figure S2. The sporulation phenotypes in wild type, S. pogona-Δsp1418 and S. pogona-Sp1418. S. pogona-Sp1418 did not produce spores or was almost invisible, and the amount of spores of S. pogona-Δsp1418 is much more than that of S. pogona, but there was no significant difference in the spore morphology of S. pogona and S. pogona-Δsp1418. Figure S3. Tricine-SDS-PAGE analysis of heterologously expressed protein Sp1418. Coomassie Brilliant Blue staining of Tricine-SDS-PAGE showing heterologous protein Sp1418 expressed in the supernatants of E. coli BL21 bearing recombinant plasmid after IPTG induction and ultrasonication. M: 66 kDa protein marker; 1: Samples from E. coli BL21 as a negative control 2: Samples from E. coli BL21 contained the recombinant plasmid. Figure S4. SDS-PAGE gel analysis of total proteins. M: Protein marker; 1: Samples from 96 h S. pogona; 2: Samples from 96 h S. pogona-Sp1418 cells; 3: Samples from 96 h S. pogona-Δsp1418 cells. Compared with the three strains, there are many distinctive bands, and totally 9 proteins were identified via 1D-LC–MS/MS. Figure S5. Construction of pKCcas9d-sgRNA-UHA-DHA and pOJ260-PermE-sp1418. A. Construction of plasmid pKCcas9d-sgRNA-UHA-DHA; B. Construction of plasmid pOJ260-PermE-sp1418.Figure S6. Recombination schematic diagram of vetor pOJ260-PermE-sp1418 and pKCcas9d-sgRNA-UHA-DHA. A. Recombination schematic diagram of vetor pOJ260-PermE-sp1418; B. Recombination schematic diagram of vetor pKCcas9d-sgRNA-UHA-DHA. Figure S7. Identification of S. pogona-Δsp1418 and S. pogona-Sp1418. A: Identification of PermE-sp1418 fragment in S. pogona and S. pogona-Sp1418. M: DL 2000 DNA marker; 1: PCR products of S. pogona with primer pair perm-F/tetR-R; 2: PCR products of S. pogona-Sp1418 with primer pair perm-F/tetR-R; B: PCR amplification of aac(3)IV gene in S. pogona and S. pogona-Sp1418. M: DL 2000 DNA marker; 1–2: PCR products of S. pogona with primer pair Apr-F/Apr-R; 3: PCR products of S. pogona-Sp1418 with primer pair Apr-F/Apr-R; C: Identification of aac(3)IV gene in S. pogona and S. pogona-Δsp1418. M: DL 2000 DNA marker; 1: PCR products of S. pogona with primers Apr-F/Apr-R; 2: PCR products of S. pogona-Δsp1418 with primers Apr-F/Apr-R; D: Identification of sp1418 gene in S. pogona and S. pogona-Δsp1418 M: DL 2000 DNA marker; 1: PCR products of S. pogona with primers tetR-P-F/tetR-P-R; 2: PCR products of S. pogona-Δsp1418 with primers tetR-P-F/tetR-P-R.

Published
2020
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34. Process on Single Channel Scanning Milling of Micro-electrical Discharge Based on Integration Mechanism

Author

Zhiqun Wu, Guangmin Liu, Rang-jie Wu, Lei Yanhua, and Yongbin Zhang

Subjects
0209 industrial biotechnology, Materials science, Process (computing), Mechanical engineering, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Pulse (physics), Mechanism (engineering), Modeling and simulation, 020901 industrial engineering & automation, Machining, Electrode, General Earth and Planetary Sciences, Electric discharge, 0105 earth and related environmental sciences, General Environmental Science, Communication channel
Abstract

During the process of three-dimensional scanning milling of micro-electrical discharge, both positive and negative poles usually present as arc shape. This phenomena is called “arc shape phenomena” in this paper. This paper is to introduce erosion mechanism of electrical pulse discharged on both. Typically, the hollow electrode is applied to modeling and simulation. And then real experiments will be conducted. There are two conditions for the electrode in the analysis and tests: rotating at 300 rpm and 0 rpm. Finally, the profiles of tool electrode and workpiece are provided. Results show that there are different erosion effects on both poles. It shows that the process parameters have a significant influence on the final machining results.

Published
2018

35. Deletion of a hybrid NRPS‐T1PKS biosynthetic gene cluster via Latour gene knockout system in Saccharopolyspora pogona and its effect on butenyl‐spinosyn biosynthesis and growth development

Author

Rang, Jie, primary, Li, Yunlong, additional, Cao, Li, additional, Shuai, Ling, additional, Liu, Yang, additional, He, Haocheng, additional, Wan, Qianqian, additional, Luo, Yuewen, additional, Yu, Ziquan, additional, Zhang, Youming, additional, Sun, Yunjun, additional, Ding, Xuezhi, additional, Hu, Shengbiao, additional, Xie, Qingji, additional, and Xia, Liqiu, additional

Published
2020
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36. Deciphering the Metabolic Pathway Difference Between Saccharopolyspora pogona and Saccharopolyspora spinosa by Comparative Proteomics and Metabonomics

Author

Rang, Jie, primary, He, Haocheng, additional, Yuan, Shuangqin, additional, Tang, Jianli, additional, Liu, Zhudong, additional, Xia, Ziyuan, additional, Khan, Tahir Ali, additional, Hu, Shengbiao, additional, Yu, Ziquan, additional, Hu, Yibo, additional, Sun, Yunjun, additional, Huang, Weitao, additional, Ding, Xuezhi, additional, and Xia, Liqiu, additional

Published
2020
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37. Deletion of a hybrid NRPS‐T1PKS biosynthetic gene cluster via Latour gene knockout system in Saccharopolyspora pogona and its effect on butenyl‐spinosyn biosynthesis and growth development.

Author

Rang, Jie, Li, Yunlong, Cao, Li, Shuai, Ling, Liu, Yang, He, Haocheng, Wan, Qianqian, Luo, Yuewen, Yu, Ziquan, Zhang, Youming, Sun, Yunjun, Ding, Xuezhi, Hu, Shengbiao, Xie, Qingji, and Xia, Liqiu

Subjects
*GENE clusters, *GENE knockout, *BIOSYNTHESIS, *SYNTHETIC genes, *REGULATOR genes, *DELETION mutation
Abstract

Summary: Butenyl‐spinosyn, a promising biopesticide produced by Saccharopolyspora pogona, exhibits stronger insecticidal activity and a broader pesticidal spectrum. However, its titre in the wild‐type S. pogona strain is too low to meet the industrial production requirements. Deletion of non‐target natural product biosynthetic gene clusters resident in the genome of S. pogona could reduce the consumption of synthetic precursors, thereby promoting the biosynthesis of butenyl‐spinosyn. However, it has always been a challenge for scientists to genetically engineer S. pogona. In this study, the Latour gene knockout system (linear DNA fragment recombineering system) was established in S. pogona. Using the Latour system, a hybrid NRPS‐T1PKS cluster (˜20 kb) which was responsible for phthoxazolin biosynthesis was efficiently deleted in S. pogona. The resultant mutant S. pogona‐Δura4‐Δc14 exhibited an extended logarithmic phase, increased biomass and a lower glucose consumption rate. Importantly, the production of butenyl‐spinosyn in S. pogona‐Δura4‐Δc14 was increased by 4.72‐fold compared with that in the wild‐type strain. qRT‐PCR analysis revealed that phthoxazolin biosynthetic gene cluster deletion could promote the expression of the butenyl‐spinosyn biosynthetic gene cluster. Furthermore, a TetR family transcriptional regulatory gene that could regulate the butenyl‐spinosyn biosynthesis has been identified from the phthoxazolin biosynthetic gene cluster. Because dozens of natural product biosynthetic gene clusters exist in the genome of S. pogona, the strategy reported here will be used to further promote the production of butenyl‐spinosyn by deleting other secondary metabolite synthetic gene clusters. [ABSTRACT FROM AUTHOR]

Published
2021
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38. Preparation and Surface Modification of SiC Quantum Dots by Controllable Chemical Etching Method.

Author

RANG Jie, SONG Yuepeng, SUN Weiyun, DING Ziyang, LI Lianrong, JIAO Can, and LEI Tengfei

Abstract

Silicon carbide quantum dots (QDs) were prepared by controllable chemical etching method, and then the aqueous solution of SiC QDs were obtained by ultrasonic cavitation and high-speed chromatography, the surface physicochemical properties of SiC QDs were controlled by chemical coupling method. The microstructure and spectral properties of SiC QDs were characterized by adjusting the preparation parameters, the results show that the main factors affect the relative photoluminescence intensity of SiC QDs are corrosion times, composition of corrosive agent and corresive agent components. Adjusting the corrosion times and the proportion of corrosive agent components, then analysis pure sulfuric acid of coupling agent is added, the relative photoluminescence intensity of water-phase SiC quantum dots is the best when V(HF) : V(HNO3): V(H2SO4) = 6:1:1 is used to corrode the milled (Β -SiC powder. At the same time, the formation mechanism and modification stability of -SH on the surface of SiC quantum dots are studied and analyzed. [ABSTRACT FROM AUTHOR]

Published
2020

39. MOESM1 of Proteomic analysis of the influence of Cu2+ on the crystal protein production of Bacillus thuringiensis X022

Author

Xuemei Liu, Mingxing Zuo, Wang, Ting, Yunjun Sun, Liu, Shuang, Shengbiao Hu, He, Hao, Yang, Qi, Rang, Jie, Meifang Quan, Liqiu Xia, and Xuezhi Ding

Abstract

Additional file 1. Figure S1. SDS-PAGE of whole proteins extracted from B. thuringiensis strain. Figure S2. Integrity detection of the RNA samples extracted. Table S1. Primers for quantitative RT-PCR analysis and 16S rRNA gene sequencing. Table S2. The list of identified proteins and their internal tryptic peptides from strain B. thuringiensis X022. Table S3. The emPAI semi-quantitative of ICPs. Table S4. The list of the proteins down-regulated when Cu2+ was added.

Published
2015
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40. Comparative Analysis of Genomics and Proteomics in the New Isolated Bacillus thuringiensis X022 Revealed the Metabolic Regulation Mechanism of Carbon Flux Following Cu2+ Treatment

Author

Quan, Meifang, primary, Xie, Junyan, additional, Liu, Xuemei, additional, Li, Yang, additional, Rang, Jie, additional, Zhang, Tong, additional, Zhou, Fengjuan, additional, Xia, Liqiu, additional, Hu, Shengbiao, additional, Sun, Yunjun, additional, and Ding, Xuezhi, additional

Published
2016
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46. Anticancer Activity of Saponins from Allium chinense against the B16 Melanoma and 4T1 Breast Carcinoma Cell.

Author

Yu, Zhihui, Zhang, Tong, Zhou, Fengjuan, Xiao, Xiuqing, Ding, Xuezhi, He, Hao, Rang, Jie, Quan, Meifang, Wang, Ting, Zuo, Mingxing, and Xia, Liqiu

Abstract

The cytotoxic substance of A. chinense saponins (ACSs) was isolated using ethanol extraction and purified with the D101 macroporous adsorption resin approach. We investigated the anticancer activity of ACSs in the B16 melanoma and 4T1 breast carcinoma cell lines. Methylthioninium chloride and hematoxylin-eosin staining with Giemsa dyestuff were used when the cells were treated with ACSs. The results showed that the cells morphologies changed significantly; ACSs induced cell death in B16 and 4T1 cells based on acridine orange/ethidium bromide double fluorescence staining, with the number and degree of apoptotic tumor cells increasing as ACS concentration increased. ACSs inhibited the proliferation of B16 and 4T1 cells in a dose-dependent manner. They also inhibited cell migration and colony formation and exhibited a concentration-dependent effect. In addition, ACSs apparently inhibited the growth of melanoma in vivo. The preliminary antitumor in vivo assay revealed that early medication positively affected tumor inhibition action and effectively protected the liver and spleen of C57 BL/6 mice from injury. This study provides evidence for the cytotoxicity of ACSs and a strong foundation for further research to establish the theoretical basis for cell death and help in the design and development of new anticancer drugs. [ABSTRACT FROM AUTHOR]

Published
2015
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47. Comparative Proteomics Reveals the Effect of the Transcriptional Regulator Sp13016 on Butenyl-Spinosyn Biosynthesis in Saccharopolysp ora pogona .

Author

Tang J, He H, Li Y, Liu Z, Xia Z, Cao L, Zhu Z, Shuai L, Liu Y, Wan Q, Luo Y, Zhang Y, Rang J, and Xia L

Subjects
Bacterial Proteins genetics, Macrolides, Proteomics, Saccharopolyspora genetics
Abstract

Butenyl-spinosyn is a highly effective and broad-spectrum biopesticide produced by Saccharopolyspora pogona . However, the yield of this compound is difficult to increase because the regulatory mechanism of secondary metabolism is still unknown. Here, the transcriptional regulator Sp13016 was discovered to be highly associated with butenyl-spinosyn synthesis and bacterial growth. Overexpression of sp13016 improved butenyl-spinosyn production to a level that was 2.84-fold that of the original strain, while deletion of sp13016 resulted in a significant decrease in yield and growth inhibition. Comparative proteomics revealed that these phenotypic changes were attributed to the influence of Sp13016 on the central carbon metabolism pathway to regulate the supply of precursors. Our research helps to reveal the regulatory mechanism of butenyl-spinosyn biosynthesis and provides a reference for increasing the yield of natural products of Actinomycetes .

Published
2021
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48. [Effect of fcl gene for butenyl-spinosyn biosynthesis and growth of Saccharopolyspora pogona].

Author

Peng S, He H, Yuan S, Rang J, Hu S, Sun Y, Yu Z, Huang W, Hu Y, Ding X, and Xia L

Subjects
Bacterial Proteins, Genetic Engineering, Insecticides, Macrolides, Saccharopolyspora
Abstract

The fcl gene encodes GDP-fucose synthase, which catalyzes two-step differential isomerase and reductase reactions in the synthesis of GDP-L-fucose from GDP-D-mannose. It also participates in the biosynthesis of amino sugar and ribose sugar, and is one of the key enzymes to regulate the metabolism of sugar and nucleotides in organisms. The presence of fcl gene in Saccharopolyspora pogona was found through sequencing result of genome. The mutant S. pogona-fcl and S. pogona-Δfcl were constructed by gene engineering technology. The results showed that the gene had an effects on growth and development, protein expression and transcriptional level, insecticidal activity, and biosynthesis of butenyl-spinosyn of Saccharopolyspora pogona. The results of HPLC analysis showed that the yield of butenyl-spinosyn in S. pogona-Δfcl was 130% compared with that in S. pogona, which reduced by 25% in S. pogona-fcl. The results of determination of insecticidal activity showed that S. pogona-Δfcl had a stronger insecticidal activity against Helicoverpa armigera than that of S. pogona, while the S. pogona-fcl had a lower insecticidal activity against Helicoverpa armigera compared with S. pogona. Scanning electron microscopy (SEM) was used to observe the morphology of the mycelia. It was found that the surface of the S. pogona-Δfcl was wrinkled, and the mycelium showed a short rod shape. There was no significant difference in mycelial morphology between S. pogona-fcl and S. pogona. Aboved all showed that deletion of fcl gene in S. pogona hindered the growth and development of mycelia, but was beneficial to increase the biosynthesis of butenyl-spinosyn and improve insecticidal activity. Whereas the fcl gene over-expression was not conducive to the biosynthesis of butenyl-spinosyn and reduced their insecticidal activity. SDS-PAGE results showed that the difference of protein expression among the three strains was most obvious at 96 hours, which was identified by real-time fluorescence quantitative polymerase chain reaction, the results showed that there were significant differences of related genes in transcriptional levels among the three strains. Based on the results of the study, a network metabolic control map was constructed to analyze the effect of fcl gene on growth and the regulation pathway of butenyl-spinosyn biosynthesis, which provided an experimental basis for revealing the regulation mechanism of butenyl-spinosyn biosynthesis and related follow-up studies.

Published
2019
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49. [Effect of ribosome engineering on butenyl-spinosyns synthesis of Saccharopolyspora pogona].

Author

Luo L, Yang Y, Wei H, Rang J, Tang Q, Hu S, Sun Y, Yu Z, Ding X, and Xia L

Subjects
Genetic Engineering, Point Mutation, Ribosomal Proteins genetics, Macrolides metabolism, Ribosomes metabolism, Saccharopolyspora metabolism
Abstract

Through introducing mutations into ribosomes by obtaining spontaneous drug resistance of microorganisms, ribosome engineering technology is an effective approach to develop mutant strains that overproduce secondary metabolites. In this study, ribosome engineering was used to improve the yield of butenyl-spinosyns produced by Saccharopolyspora pogona by screening streptomycin resistant mutants. The yields of butenyl-spinosyns were then analyzed and compared with the parent strain. Among the mutants, S13 displayed the greatest increase in the yield of butenyl-spinosyns, which was 1.79 fold higher than that in the parent strain. Further analysis of the metabolite profile of S13 by mass spectrometry lead to the discovery of Spinosyn α1, which was absent from the parent strain. DNA sequencing showed that there existed two point mutations in the conserved regions of rpsL gene which encodes ribosomal protein S12 in S13. The mutations occurred a C to A and a C to T transversion mutations occurred at nucleotide pair 314 and 320 respectively, which resulted in the mutations of Proline (105) to Gultamine and Alanine (107) to Valine. It also demonstrated that S13 exhibited genetic stability even after five passages.

Published
2016

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