1.Breeding of high-producing LI-F lipopeptide Paenibacillus polymyxa by protoplast fusion and differential expression analysis of fusion strains.
Dong YAN ; Jinzhi HAN ; Xiaomei BIE ; Zhaoxin LU ; Fengxia LÜ ; Haizhen ZHAO ; Chong ZHANG
Chinese Journal of Biotechnology 2015;31(9):1401-1407
Auxotrophic strains of N1-37 (Phe-) and N2-27 (His-), screened from mutations of Paenibacillus polymyxa JSa-9 previously, were used as the parent strains to screen high-producing LI-F antibacterial lipopeptide fusion strain through protoplast fusion with polyethylene glycol as a promote agent. Fusion strain F5-15 was obtained. Then the product of LI-F antibacterial lipopeptide was quantified by HPLC, and the difference of expression of the key genes of lipopeptide synthase between wild strain JSa-9 and the fusion strain was analyzed by real-time PCR. LI-F antibacterial lipopeptide yield of the fusion strain F5-15 was 3.1-fold of the original strain JSa9's, and the expression levels of the target genes were 10.48, 2.48, 2.1 and 11.8 fold of the initial strain JSa-9, respectively.
Anti-Bacterial Agents
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biosynthesis
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Chromatography, High Pressure Liquid
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Lipopeptides
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biosynthesis
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Paenibacillus
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metabolism
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Protoplasts
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metabolism
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Real-Time Polymerase Chain Reaction
2.Cloning and expression of lipoxygenase gene from Anabaena sp. PCC 7120 and purification, characterization of the recombinant enzyme.
Chong ZHANG ; Xiaowei ZHOU ; Fengxia LÜ ; Xiaomei BIE ; Tingting TAO ; Qi YING ; Zhaoxin LU
Chinese Journal of Biotechnology 2012;28(4):440-456
We cloned the lipoxygenase gene (ana-LOX) from Anabaena sp. PCC 7120 and expressed it in Escherichia coli BL21 (DE3) pLysS. We determined the active site of the recombinant ana-LOX through site-directed gene mutagenesis and obtained the shortest length of the functional gene. Meanwhile, we studied the properties of recombinant ana-LOX after purification. The C-terminal of the Aos (allene oxide synthase)-LOX fusion gene in Anabaena sp. PCC 7120 genome was found belonging to LOXs family by bioinformatics analysis. Further results of site-directed gene mutagenesis confirmed that the active sites of ana-LOX were His197, His202, His369, Asn373and Ile455. The shortest length of functional gene was identified to be 1 254 bp based on the strategy of shortening the gene length gradually. The highest activity of recombinant ana-LOX of 6 750 U/mL could be achieved when constructed to pET-32a vector and expressed at low temperature 16 degrees C. We purified the enzyme by Ni-NTA chelating affinity chromatography, with 60.89% yield and specific activity of 11.4 x 10(4) U/mg. The optimum reaction temperature and pH for ana-LOX were 45 degrees C and 6.0, respectively. Furthermore, the obtained ana-LOX was stable at room temperature. The effect of metal ions on ana-LOX was determined also. Fe2+, Mg2+ Ca2+ could markedly promote the activity of this enzyme whereas Fe3+ and Cu2+ had a strong inhibitory effect on it. Finally, the ana-LOX could improve the microscopical structure of dough. The results of this study will provide a basis for future improvements and food industrial applications of ana-LOX.
Anabaena
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enzymology
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genetics
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Catalytic Domain
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Cloning, Molecular
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Enzyme Stability
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Escherichia coli
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metabolism
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Lipoxygenase
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chemistry
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genetics
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Metals, Heavy
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chemistry
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Mutagenesis, Site-Directed
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Recombinant Proteins
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chemistry
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genetics
3.Cloning and expression of organic solvent tolerant lipase gene from Staphylococcus saprophyticus M36.
Yanchong TANG ; Yaping LU ; Fengxia LÜ ; Xiaomei BIE ; Yao GUO ; Zhaoxin LU
Chinese Journal of Biotechnology 2009;25(12):1989-1995
Lipases are important biocatalysts that are widely used in food processing and bio-diesel production. However, organic solvents could inactivate some lipases during applications. Therefore, the efficient cloning and expression of the organic solvent-tolerant lipase is important to its application. In this work, we first found out an organic solvent-tolerant lipase from Staphylococcus saprophyticus M36 and amplified the 741 bp Lipase gene lip3 (GenBank Accession No. FJ979867), by PCR, which encoded a 31.6 kD polypeptide of 247 amino acid residues. But the lipase shared 83% identity with tentative lip3 gene of Staphylococcus saprophyticus (GenBank Accession No. AP008934). We connected the gene with expression vector pET-DsbA, transformed it into Escherichia coli BL21 (DE3), and obtained the recombinant pET-DsbA-lip3. With the induction by 0.4 mmol/L of isopropyl beta-D-thiogalactopyranoside at pH 8.0, OD600 1.0, 25 degrees C for 12 h, the lipase activity reached up to 25.8 U/mL. The lipase expressed was stable in the presence of methanol, n-hexane, and isooctane, n-heptane.
Amino Acid Sequence
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Base Sequence
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Cloning, Molecular
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Enzyme Stability
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Escherichia coli
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genetics
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metabolism
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Lipase
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biosynthesis
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genetics
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Molecular Sequence Data
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Organic Chemicals
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chemistry
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Recombinant Proteins
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biosynthesis
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genetics
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Solvents
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chemistry
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Staphylococcus saprophyticus
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enzymology
4.Fusion expression of fibrinolytic enzyme gene PPFE-I from endophytic Paenibacillus polymyxa in Escherichia coli and activity analysis.
Fengxia LÜ ; Zhaoxin LU ; Xiaomei BIE ; Qian LIN ; Chong ZHANG ; Lin CAO ; Yao GUO ; Yanchong TANG
Chinese Journal of Biotechnology 2010;26(8):1128-1134
With the genomic DNA of strain EJS-3 as the template, we amplified the gene of fibrinolytic enzyme from Paenibacillus polymyxa (PPFE-I) by PCR. We purified the PCR product and ligated it into pMD19-T. After DNA sequencing, we cloned the PPFE-I gene into expression vector pET-DsbA and transformed it into Escherichia coli BL21(DE3). Upon induction of IPTG, we found that the activity of recombinant fibrinolytic enzyme fused with DsbA expressed in Escherichia coli was 228 IU/mL. SDS-PAGE analysis showed that the recombinant enzyme was soluble and accounted for about 18.4% of total cell protein. Western blotting demonstrated that the recombinant protein was DsbA-PPFE-I. We purified the recombinant enzyme by Ni affinity chromatography, thrombin digestion and sephadex G-100 gel-filtration, and identified the molecular weight of purified product to be 66.3 kDa with MALDI-TOF mass spectrometry. The purified enzyme exhibited distinct fibrinolytic activity on fibrin plate.
Antifibrinolytic Agents
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pharmacology
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Cloning, Molecular
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Escherichia coli
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genetics
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metabolism
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Fibrinolytic Agents
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metabolism
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Genetic Vectors
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genetics
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Paenibacillus
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chemistry
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enzymology
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Recombinant Fusion Proteins
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biosynthesis
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genetics
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pharmacology