AIM: To explore the possibility of expressing hepatitis C virus (HCV) envelope protein 1 (E1) in Escherichia coli (E. coli)and to test the purified recombinant E1 proteins for clinical and research applications.METHOD...AIM: To explore the possibility of expressing hepatitis C virus (HCV) envelope protein 1 (E1) in Escherichia coli (E. coli)and to test the purified recombinant E1 proteins for clinical and research applications.METHODS: C-terminally truncated E1 fragments were expressed in E. coli as hexa-histidine-tagged fusion proteins. The expression products were purified under denaturing conditions using immobilized-metal affinity chromatography. Purified E1 proteins were used to immunize rabbits. Rabbit anti-sera thus obtained were reacted with both E. coli- and mammalian cell-expressed E1 glycoproteins as detected by Western blot.RESULTS: Full-length E1 protein proved difficult to express in E. coli. C-terminally truncated E1 was successfully expressed in E. colias hexa-histidine-tagged recombinant fusion protein and was purified under denaturing conditionson Ni^2+-NTA agarose. Rabbit anti-sera raised against purified recombinant E1 specifically reacted with mammalian cell-expressed E1 giycoproteins in Western blot. Furthermore, E. coli-derived E1 protein was able to detect animal antibodies elicited by El-based DNA immunization.CONCLUSION: These results demonstrate that the prokaryotically expressed E1 proteins share identical epitopes with eukaryotically expressed E1 glycoprotein. The E. coli-derived E1 proteins and corresponding antisera can become useful tools in anti-HCV vaccine research.展开更多
Sweet potato is one of the first natural GMOs, genetically modified 8000 years ago by Agrobacterium rhizogenes as reported recently by Kyndt et al. A section of 10 kbp long DNA (Transferred- DNA or T-DNA) of the Ri (R...Sweet potato is one of the first natural GMOs, genetically modified 8000 years ago by Agrobacterium rhizogenes as reported recently by Kyndt et al. A section of 10 kbp long DNA (Transferred- DNA or T-DNA) of the Ri (Root-inducing) plasmid was transferred to the plant genome by A. rhizo-genes and has been maintained in all 291 hexaploid sweet potato cultivars of the world. The maintenance in the sweet potato genome and expression of two T-DNA genes for tryptophan-2-monooxygenease (iaaM) and for indole-3-acetamide hydrolase (iaaH) are likely to be physiologically significant since these enzymes convert tryptophan to indole-3-acetic acid, a major plant growth hormone auxin. Sweet potato (Ipomoea batatas (L.) Lam) is ranked the third most important root crop after potato and cassava, and the seventh in global food crop production with more than 126 million metric tons. Although sweet potato originated in Central or South America, China currently produces over 86% of world production with 109 million metric tons. In the United States, North Carolina is the leading producer with 38.5% of the 2007 sweet potato production, followed by California, Mississippi, and Louisiana with 23%, 19%, and 15.9%, respectively. Leaf curl virus diseases have been reported in sweet potato throughout the world. One of the causal agents is Sweet potato leaf curl virus (SPLCV) belonging to the genus Begomovirus (family Geminiviridae). Although SPLCV does not cause symptoms on Beauregard, one of the most predominant sweet potato cultivars in the US, it can reduce the yield up to 26%. Serological detection of SPLCV is not currently available due to the difficulties in obtaining purified virions that can be used as antigen for antiserum production. In attempts to obtain the coat protein (CP) of SPLCV for antibody production, primers were designed to amplify the CP gene. This gene was cloned into the expression vector pMAL-c2E as a fusion protein with maltose-binding protein, and transformed into Escherichia coli strain XL1-Blue. After gene induction, a fusion protein of 72 kDa was purified by amylose affinity chromatography. The yield of the purified fusion protein was approximately 200 μg/liter of bacterial culture. Digestion with enterokinase cleaved the fusion protein into a 42.5 kDa maltosebinding protein and a 29.4 kDa protein. The latter protein was identified by mass spectrometry analysis as the coat protein of SPLCV based on the fact that the mass spectrometry elucidated the sequences corresponding to 37% of amino acid positions of the SPLCV coat protein.展开更多
SsrA peptide tag from Mycoplasma fl orum has been developed as a versatile biotechnology tool to control orthogonal degradation of tagged proteins in Escherichia coli . Here, using the systematic deletion mutants of m...SsrA peptide tag from Mycoplasma fl orum has been developed as a versatile biotechnology tool to control orthogonal degradation of tagged proteins in Escherichia coli . Here, using the systematic deletion mutants of mf -ssrA tag, we demonstrated that the residues in two separate regions have diff erent functions in mf -Lon-mediated specifi c orthogonal target protein degradation in E. coli . The deletion of multiple residues, up to six amino acids, did not fatally abolish its specifi c degradation activity, instead of being able to improve the stability of the tagged protein in the presence of endogenous proteases before mf -Lon expression in E. coli . Except for previously identifi ed essential residues, the region adjacent to the C-terminal of the mf -ssrA tag was involved in mf -Lon and endogenous protease-mediated degradation. Moreover, the deletion of specifi c residues made the mf -ssrA tag more eff ective and compact. The mf -ssrA tag can be implemented in synthetic biology and bioengineering for development of synthetic circuits.展开更多
IbeA is an important invasion determinant contributing to Escherichia coli K1 entry into brain microvascular endothelial cells (BMEC) that is a key step in the pathogenesis of E. coli meningitis. Our previous studies ...IbeA is an important invasion determinant contributing to Escherichia coli K1 entry into brain microvascular endothelial cells (BMEC) that is a key step in the pathogenesis of E. coli meningitis. Our previous studies have shown that IbeA-induced signaling and E. coli K1 invasion is mediated by two IbeA-binding proteins, vimentin, which is constitutively present in the surface of human BMECs (HBMECs), and PSF, which is inducibly expressed in both mesenchymal (endothelium) and non-mesenchymal (epithelium) cells. However, it is unknown whether p54nrb, a PSF partner protein, could contribute to the pathogenesis of E. coli K1 meningitis. Here, we reported that a 54-kDa protein was identified by copurification with PSF through IbeA-affinity chromatography as an IbeA-binding protein, which is identical to p54nrb. Both p54nrb and PSF are RNA-binding proteins and share significant sequence homology. The specific interaction between IbeA and p54nrb was confirmed by Western blot and ligand overlay assays. Recombinant p54nrb blocked E. coli K1 invasion of human BMEC very effectively. Overexpressed p54nrb as a GFP fusion protein in the transfected 293T cells significantly enhanced E. coli K1 invasion. Furthermore, higher levels of surface p54nrb in the transfected 293T cells were detected by flow cytometry. These results suggest that the IbeA invasion protein of E. coli K1 interacts with p54nrb for bacterial invasion of human BMEC.展开更多
Objective:To express the soluble recombinant hemangiopoietin protein in E.coli BL21(DE3).Methods:Using human fetal live cDNA as a template,a partial cDNA fragment of HAPO coding N-terminal region was subcloned into pl...Objective:To express the soluble recombinant hemangiopoietin protein in E.coli BL21(DE3).Methods:Using human fetal live cDNA as a template,a partial cDNA fragment of HAPO coding N-terminal region was subcloned into plasmids pTrc99,pQE60 and pET32c to construct different recombinant prokaryotic expression systems.After selecting,the soluble rhHAPO fusion protein was expressed stably in E.coli BL21(DE3) by vector pET32c-HAPO and further isolated by nickelnitrilotriacetic acid(NTA) affinity chromatography.After cleavage with enterokinase,the rhHAPO protein was applied to Fast Flow SP sepharose column.Results:The rhHAPO protein had a purity of more than 95% and a good bioactivity based on the cell adhesion assay in ECV304 cells.Conclusion:We have established a protein engineering system to produce rhHAPO which may provide the possibility for clinical application.展开更多
AIM: To study the influence of redox environment of Escherichia coli ( E. coli) cytoplasm on disulfide bond formation of recombinant proteins.METHODS: Bovine fibroblast growth factor (BbFGF) was selected as a model of...AIM: To study the influence of redox environment of Escherichia coli ( E. coli) cytoplasm on disulfide bond formation of recombinant proteins.METHODS: Bovine fibroblast growth factor (BbFGF) was selected as a model of simple proteins with a single disulfide bond and free cysteines. Anti-HBsAg single-chain Fv (HBscFv), an artificial multidomain protein, was selected as the model molecule of complex protein with 2 disulfide bonds. A BbFGF-producing plasmid, pJN-BbFGF,and a HBscFv producing-plasmid, pQE-HBscFv, were constructed and transformed into E. coli strains BL21(DE3)and M15[pREP4]respectively. At the same time, both plasmids were transformedinto a reductase-deficient host strain, E. coli Origami(DE3). The 4 recombinant E. coli strains were cultured and the target proteins were purified. Solubility and bioactivity of recombinant BbFGF and HBscFv produced in different host strains were analyzed and compared respectively.RESULTS: All recombinant E. colistrains could efficiently produce target proteins. The level of BbFGF in BL21(DE3)was 15-23% of the total protein, and was 5-10% in Origami (DE3). In addition, 65% of the BbFGF produced in BL21(DE3) formed into inclusion body in the cytoplasm,and all the target proteins became soluble in Origami (DE3). The bioactivity of BbFGF purified from Origami(DE3)was higher than its counterpart from BL21(DE3). The ED50of BbFGF from Origami(DE3) and BL21(DE3) was 1.6 μg/L and 2.2 μg/L, respectively. Both HBscFv formed into inclusion body in the cytoplasm of M15[pQE-HBscFv] or Origami[pQE-HBscFv]. But the supernatant of Origami[pQE-HBscFv] lysate displayed weak bioactivity and its counterpart from M15[pQE-HBscFv] did not display any bioactivity. The soluble HBscFv in Origami[pQE-HBscFv]was purified to be 1-2 mg/L and its affinity constant was determined to be 2.62×107 mol/L. The yield of native HBscFv refolded from indusion body in M15[pQE-H Fv] was30-35 mg/L and the affinity constant was 1.98×107 mol/L.There was no significant difference between the bioactivity of HBscFvs refolded from the inclusion bodies produced in different host strains.CONCLUSION: Modification of the redox environment of E. coli cytoplasm can significantly improve the folding of recombinant disulfide-bonded proteins produced in it.展开更多
Bacteria have long been the favorite expression system for recombinant protein production.However,the flaw of the system is that insoluble and inactive proteins are co-produced due to codon bias,protein folding,phosph...Bacteria have long been the favorite expression system for recombinant protein production.However,the flaw of the system is that insoluble and inactive proteins are co-produced due to codon bias,protein folding,phosphorylation,glycosylation,mRNA stability and promoter strength.Factors are cited and the methods to convert to soluble and active proteins are described,for example a tiglit control of Escherichia coli milieu,refolding from inclusion body and through fusion technology.展开更多
A great amount of foodborne pathogens were Gram-positive(G+) bacteria, a threat to public health. In this study, considering the binding ability of nisin towards G+ bacteria and the stable fluorescent ability of EGFP ...A great amount of foodborne pathogens were Gram-positive(G+) bacteria, a threat to public health. In this study, considering the binding ability of nisin towards G+ bacteria and the stable fluorescent ability of EGFP protein, a fluorescent nisin–EGFP protein probe was constructed by a gene engineering method. Nisin and EGFP were used as the receptor and fluorophore, respectively, to detect G+ bacteria. The nisin and egfp gene were amplified separately according to the sequence published in Gen Bank using unique primers. The two genes were cloned into a pET-28b(+) vector resulting in apET-28b(+)–nisin–egfp vector. The vector was transferred into Escherichia coli(E. coli) BL21(DE3) for expression. The expressed protein was extracted, purified by a Ni–NTA column, and then tested by the SDS-PAGE method to confirm its molecular weight. Listeria monocytogenes(L.monocytogenes), Staphylococcus aureus(S. aureus), and Micrococcus luteus(M. luteus) were used as the representations of G+ bacteria. E. coli O157, representing the gram-negative(G-) bacteria, was used as a negative control. The binding specificity of the recombinant protein was performed on two types of bacteria and then detected through fluorescent microscopy. The results indicated that the nisin–EGFP probe could detect G+ bacteria at 10~8CFU/mL.展开更多
The aims of this work were to: i) purify GST-fusion protein from bacterial cell extracts of Escherichia coli;ii) quantify the protein by SDS PAGE and Bradford assay;iii) determine protein-DNA interaction of the purifi...The aims of this work were to: i) purify GST-fusion protein from bacterial cell extracts of Escherichia coli;ii) quantify the protein by SDS PAGE and Bradford assay;iii) determine protein-DNA interaction of the purified protein by Electrophoretic Mobility Shift Assay. Bacterial culture prepared by inoculation of a single E. coli colony that had a GST fusion protein (gst: six-X10 hd) constructed by ligation of the six-7-hd (X10) sequence into the BamHI and EcoRI sites of the vector pGEX-2T, grown overnight, was sonicated using Cole-Palmer Ultrasonic Homogenizer. Fusion protein was eluted from the beads with Tris-glutathione buffer (50 mM Tris [pH 8.1], 20 mM glutathione), which contained reduced Glutathione. SDS-PAGE was used to calculate the extracted bound protein. Total protein quantification was then estimated by the Bradford assay. Bovine Serum Albumin (BSA) absorbance values were used to plot the standard curve used to calculate the concentrations of the sample proteins. Nylon membrane was used for the electrophoretic transfer;membrane was cross linked and detected by Pierce’s Chemiluminescent Nucleic Acid Detection module. Results showed that X10 gave a strong band shift observed in Lanes 6 and 7 for both 200 ng and 400 ng elute 1 samples;however, there was no shift in the bands for the wild-type, positive control. The concentration of the elute 1 was obtained by the Bradford assay as 242.52 ng/μl and that of elute 2 was 106.30 ng/μl. Similarly, the result obtained by gel analysis was 300 ng/μl (0.3 μg/μl) and 150 ng/μl (0.15 μg/μl) for elutes 1 and 2 respectively.展开更多
基金Supported by National High Technology Research and Development Program of China (863 Program), No. 2001AA215171
文摘AIM: To explore the possibility of expressing hepatitis C virus (HCV) envelope protein 1 (E1) in Escherichia coli (E. coli)and to test the purified recombinant E1 proteins for clinical and research applications.METHODS: C-terminally truncated E1 fragments were expressed in E. coli as hexa-histidine-tagged fusion proteins. The expression products were purified under denaturing conditions using immobilized-metal affinity chromatography. Purified E1 proteins were used to immunize rabbits. Rabbit anti-sera thus obtained were reacted with both E. coli- and mammalian cell-expressed E1 glycoproteins as detected by Western blot.RESULTS: Full-length E1 protein proved difficult to express in E. coli. C-terminally truncated E1 was successfully expressed in E. colias hexa-histidine-tagged recombinant fusion protein and was purified under denaturing conditionson Ni^2+-NTA agarose. Rabbit anti-sera raised against purified recombinant E1 specifically reacted with mammalian cell-expressed E1 giycoproteins in Western blot. Furthermore, E. coli-derived E1 protein was able to detect animal antibodies elicited by El-based DNA immunization.CONCLUSION: These results demonstrate that the prokaryotically expressed E1 proteins share identical epitopes with eukaryotically expressed E1 glycoprotein. The E. coli-derived E1 proteins and corresponding antisera can become useful tools in anti-HCV vaccine research.
文摘Sweet potato is one of the first natural GMOs, genetically modified 8000 years ago by Agrobacterium rhizogenes as reported recently by Kyndt et al. A section of 10 kbp long DNA (Transferred- DNA or T-DNA) of the Ri (Root-inducing) plasmid was transferred to the plant genome by A. rhizo-genes and has been maintained in all 291 hexaploid sweet potato cultivars of the world. The maintenance in the sweet potato genome and expression of two T-DNA genes for tryptophan-2-monooxygenease (iaaM) and for indole-3-acetamide hydrolase (iaaH) are likely to be physiologically significant since these enzymes convert tryptophan to indole-3-acetic acid, a major plant growth hormone auxin. Sweet potato (Ipomoea batatas (L.) Lam) is ranked the third most important root crop after potato and cassava, and the seventh in global food crop production with more than 126 million metric tons. Although sweet potato originated in Central or South America, China currently produces over 86% of world production with 109 million metric tons. In the United States, North Carolina is the leading producer with 38.5% of the 2007 sweet potato production, followed by California, Mississippi, and Louisiana with 23%, 19%, and 15.9%, respectively. Leaf curl virus diseases have been reported in sweet potato throughout the world. One of the causal agents is Sweet potato leaf curl virus (SPLCV) belonging to the genus Begomovirus (family Geminiviridae). Although SPLCV does not cause symptoms on Beauregard, one of the most predominant sweet potato cultivars in the US, it can reduce the yield up to 26%. Serological detection of SPLCV is not currently available due to the difficulties in obtaining purified virions that can be used as antigen for antiserum production. In attempts to obtain the coat protein (CP) of SPLCV for antibody production, primers were designed to amplify the CP gene. This gene was cloned into the expression vector pMAL-c2E as a fusion protein with maltose-binding protein, and transformed into Escherichia coli strain XL1-Blue. After gene induction, a fusion protein of 72 kDa was purified by amylose affinity chromatography. The yield of the purified fusion protein was approximately 200 μg/liter of bacterial culture. Digestion with enterokinase cleaved the fusion protein into a 42.5 kDa maltosebinding protein and a 29.4 kDa protein. The latter protein was identified by mass spectrometry analysis as the coat protein of SPLCV based on the fact that the mass spectrometry elucidated the sequences corresponding to 37% of amino acid positions of the SPLCV coat protein.
基金supported by the National Natural Science Foundation of China (No. 21476167 and No. 21778039)
文摘SsrA peptide tag from Mycoplasma fl orum has been developed as a versatile biotechnology tool to control orthogonal degradation of tagged proteins in Escherichia coli . Here, using the systematic deletion mutants of mf -ssrA tag, we demonstrated that the residues in two separate regions have diff erent functions in mf -Lon-mediated specifi c orthogonal target protein degradation in E. coli . The deletion of multiple residues, up to six amino acids, did not fatally abolish its specifi c degradation activity, instead of being able to improve the stability of the tagged protein in the presence of endogenous proteases before mf -Lon expression in E. coli . Except for previously identifi ed essential residues, the region adjacent to the C-terminal of the mf -ssrA tag was involved in mf -Lon and endogenous protease-mediated degradation. Moreover, the deletion of specifi c residues made the mf -ssrA tag more eff ective and compact. The mf -ssrA tag can be implemented in synthetic biology and bioengineering for development of synthetic circuits.
文摘IbeA is an important invasion determinant contributing to Escherichia coli K1 entry into brain microvascular endothelial cells (BMEC) that is a key step in the pathogenesis of E. coli meningitis. Our previous studies have shown that IbeA-induced signaling and E. coli K1 invasion is mediated by two IbeA-binding proteins, vimentin, which is constitutively present in the surface of human BMECs (HBMECs), and PSF, which is inducibly expressed in both mesenchymal (endothelium) and non-mesenchymal (epithelium) cells. However, it is unknown whether p54nrb, a PSF partner protein, could contribute to the pathogenesis of E. coli K1 meningitis. Here, we reported that a 54-kDa protein was identified by copurification with PSF through IbeA-affinity chromatography as an IbeA-binding protein, which is identical to p54nrb. Both p54nrb and PSF are RNA-binding proteins and share significant sequence homology. The specific interaction between IbeA and p54nrb was confirmed by Western blot and ligand overlay assays. Recombinant p54nrb blocked E. coli K1 invasion of human BMEC very effectively. Overexpressed p54nrb as a GFP fusion protein in the transfected 293T cells significantly enhanced E. coli K1 invasion. Furthermore, higher levels of surface p54nrb in the transfected 293T cells were detected by flow cytometry. These results suggest that the IbeA invasion protein of E. coli K1 interacts with p54nrb for bacterial invasion of human BMEC.
基金the Natural Science Foundation of China (30300186)the Grant of 863 projects from the Ministry of Science & Technology of China (2002AA223354)
文摘Objective:To express the soluble recombinant hemangiopoietin protein in E.coli BL21(DE3).Methods:Using human fetal live cDNA as a template,a partial cDNA fragment of HAPO coding N-terminal region was subcloned into plasmids pTrc99,pQE60 and pET32c to construct different recombinant prokaryotic expression systems.After selecting,the soluble rhHAPO fusion protein was expressed stably in E.coli BL21(DE3) by vector pET32c-HAPO and further isolated by nickelnitrilotriacetic acid(NTA) affinity chromatography.After cleavage with enterokinase,the rhHAPO protein was applied to Fast Flow SP sepharose column.Results:The rhHAPO protein had a purity of more than 95% and a good bioactivity based on the cell adhesion assay in ECV304 cells.Conclusion:We have established a protein engineering system to produce rhHAPO which may provide the possibility for clinical application.
基金Supported by the National Natural Science Foundation of China,No. 30371661 and No. 30400071and the Natural Science Foundation for Research Team of Guangdong Province, China, No. 2004E039213
文摘AIM: To study the influence of redox environment of Escherichia coli ( E. coli) cytoplasm on disulfide bond formation of recombinant proteins.METHODS: Bovine fibroblast growth factor (BbFGF) was selected as a model of simple proteins with a single disulfide bond and free cysteines. Anti-HBsAg single-chain Fv (HBscFv), an artificial multidomain protein, was selected as the model molecule of complex protein with 2 disulfide bonds. A BbFGF-producing plasmid, pJN-BbFGF,and a HBscFv producing-plasmid, pQE-HBscFv, were constructed and transformed into E. coli strains BL21(DE3)and M15[pREP4]respectively. At the same time, both plasmids were transformedinto a reductase-deficient host strain, E. coli Origami(DE3). The 4 recombinant E. coli strains were cultured and the target proteins were purified. Solubility and bioactivity of recombinant BbFGF and HBscFv produced in different host strains were analyzed and compared respectively.RESULTS: All recombinant E. colistrains could efficiently produce target proteins. The level of BbFGF in BL21(DE3)was 15-23% of the total protein, and was 5-10% in Origami (DE3). In addition, 65% of the BbFGF produced in BL21(DE3) formed into inclusion body in the cytoplasm,and all the target proteins became soluble in Origami (DE3). The bioactivity of BbFGF purified from Origami(DE3)was higher than its counterpart from BL21(DE3). The ED50of BbFGF from Origami(DE3) and BL21(DE3) was 1.6 μg/L and 2.2 μg/L, respectively. Both HBscFv formed into inclusion body in the cytoplasm of M15[pQE-HBscFv] or Origami[pQE-HBscFv]. But the supernatant of Origami[pQE-HBscFv] lysate displayed weak bioactivity and its counterpart from M15[pQE-HBscFv] did not display any bioactivity. The soluble HBscFv in Origami[pQE-HBscFv]was purified to be 1-2 mg/L and its affinity constant was determined to be 2.62×107 mol/L. The yield of native HBscFv refolded from indusion body in M15[pQE-H Fv] was30-35 mg/L and the affinity constant was 1.98×107 mol/L.There was no significant difference between the bioactivity of HBscFvs refolded from the inclusion bodies produced in different host strains.CONCLUSION: Modification of the redox environment of E. coli cytoplasm can significantly improve the folding of recombinant disulfide-bonded proteins produced in it.
基金supported by Queen Saovabha Memorial Institute,The Thai Red Cross Socity
文摘Bacteria have long been the favorite expression system for recombinant protein production.However,the flaw of the system is that insoluble and inactive proteins are co-produced due to codon bias,protein folding,phosphorylation,glycosylation,mRNA stability and promoter strength.Factors are cited and the methods to convert to soluble and active proteins are described,for example a tiglit control of Escherichia coli milieu,refolding from inclusion body and through fusion technology.
基金supported by the National Key Technology Research and Development Program of the Ministry of Science and Technology of China (No. 2015BAD16B01)TianjinKey Technology Research and Development Support Program (No. 13ZCDNC01900)
文摘A great amount of foodborne pathogens were Gram-positive(G+) bacteria, a threat to public health. In this study, considering the binding ability of nisin towards G+ bacteria and the stable fluorescent ability of EGFP protein, a fluorescent nisin–EGFP protein probe was constructed by a gene engineering method. Nisin and EGFP were used as the receptor and fluorophore, respectively, to detect G+ bacteria. The nisin and egfp gene were amplified separately according to the sequence published in Gen Bank using unique primers. The two genes were cloned into a pET-28b(+) vector resulting in apET-28b(+)–nisin–egfp vector. The vector was transferred into Escherichia coli(E. coli) BL21(DE3) for expression. The expressed protein was extracted, purified by a Ni–NTA column, and then tested by the SDS-PAGE method to confirm its molecular weight. Listeria monocytogenes(L.monocytogenes), Staphylococcus aureus(S. aureus), and Micrococcus luteus(M. luteus) were used as the representations of G+ bacteria. E. coli O157, representing the gram-negative(G-) bacteria, was used as a negative control. The binding specificity of the recombinant protein was performed on two types of bacteria and then detected through fluorescent microscopy. The results indicated that the nisin–EGFP probe could detect G+ bacteria at 10~8CFU/mL.
文摘The aims of this work were to: i) purify GST-fusion protein from bacterial cell extracts of Escherichia coli;ii) quantify the protein by SDS PAGE and Bradford assay;iii) determine protein-DNA interaction of the purified protein by Electrophoretic Mobility Shift Assay. Bacterial culture prepared by inoculation of a single E. coli colony that had a GST fusion protein (gst: six-X10 hd) constructed by ligation of the six-7-hd (X10) sequence into the BamHI and EcoRI sites of the vector pGEX-2T, grown overnight, was sonicated using Cole-Palmer Ultrasonic Homogenizer. Fusion protein was eluted from the beads with Tris-glutathione buffer (50 mM Tris [pH 8.1], 20 mM glutathione), which contained reduced Glutathione. SDS-PAGE was used to calculate the extracted bound protein. Total protein quantification was then estimated by the Bradford assay. Bovine Serum Albumin (BSA) absorbance values were used to plot the standard curve used to calculate the concentrations of the sample proteins. Nylon membrane was used for the electrophoretic transfer;membrane was cross linked and detected by Pierce’s Chemiluminescent Nucleic Acid Detection module. Results showed that X10 gave a strong band shift observed in Lanes 6 and 7 for both 200 ng and 400 ng elute 1 samples;however, there was no shift in the bands for the wild-type, positive control. The concentration of the elute 1 was obtained by the Bradford assay as 242.52 ng/μl and that of elute 2 was 106.30 ng/μl. Similarly, the result obtained by gel analysis was 300 ng/μl (0.3 μg/μl) and 150 ng/μl (0.15 μg/μl) for elutes 1 and 2 respectively.