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− | <a href="# | + | <a href="#Results"style="font-size:14px" >Results</a> |
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<p style="text-align:center"><b>Figure Standard</b> Relationship between voltage data and concentration.</p> | <p style="text-align:center"><b>Figure Standard</b> Relationship between voltage data and concentration.</p> | ||
− | Following the method above , we obtain the rate of hydrogen evolution: the tip of the first period is 7.061 mV at 500s. This corresponds to 2.179 (0.3086*7.061) umol/L at 500s. Thus the rate is 0.0126 (2.179/500*3mL*1000) umol/s, for 0.1g E. | + | Following the method above , we obtain the rate of hydrogen evolution: the tip of the first period is 7.061 mV at 500s. This corresponds to 2.179 (0.3086*7.061) umol/L at 500s. Thus the rate is 0.0126 (2.179/500*3mL*1000) umol/s, for 0.1g <i>E. coli</i>. In comparison with the rate from reference 1, 0.0086mol umol/s. This 46% increase in the efficiency shows that our system not only functions, but is also a big improvement compared with a artificial hydrogen production system reported before .<p></p> |
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<h4><b>Characterization</b></h4> | <h4><b>Characterization</b></h4> | ||
− | As Figure3 illustrated, His-CsgA-SpyCatcher-Histag mutant incubated with mCherry-SpyTag show a clear biofilm-associated mcherry fluorescence signal, which indicating the accurate conformation and function of the SpyTag and SpyCatcher linkage system. The third figure is merged by the first and second figures of each sample are snapped respectively under green laser field with 558 nm wavelength and bright field of fluorescence microscopy, Zeiss Axio Imager Z2. As for controls, strains secreted CsgA–Histag and ΔCsgA both are unable to specifically attach to SpyTag thus no distinct localization highlight of red fluorescence on E.coli. That to a large extent prove the specificity of our desired linkage between SpyTag and SpyCatcher system. <p></p> | + | As Figure3 illustrated, His-CsgA-SpyCatcher-Histag mutant incubated with mCherry-SpyTag show a clear biofilm-associated mcherry fluorescence signal, which indicating the accurate conformation and function of the SpyTag and SpyCatcher linkage system. The third figure is merged by the first and second figures of each sample are snapped respectively under green laser field with 558 nm wavelength and bright field of fluorescence microscopy, Zeiss Axio Imager Z2. As for controls, strains secreted CsgA–Histag and ΔCsgA both are unable to specifically attach to SpyTag thus no distinct localization highlight of red fluorescence on <i>E. coli</i>. That to a large extent prove the specificity of our desired linkage between SpyTag and SpyCatcher system. <p></p> |
<center> | <center> | ||
<img src="https://static.igem.org/mediawiki/parts/5/5c/Shanghaitechchina_mcherry-SpyTag%2BCsgA-SpyCatcher.png" style="width:100%;"> | <img src="https://static.igem.org/mediawiki/parts/5/5c/Shanghaitechchina_mcherry-SpyTag%2BCsgA-SpyCatcher.png" style="width:100%;"> | ||
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<h1 align="center" >Conclusion</h1> | <h1 align="center" >Conclusion</h1> | ||
− | In conclusion, E. | + | In conclusion, <i>E. coli</i> strains expressing biofilm on microspheres to anchor nanorods and strains expressing hydrogenase work great together for producing hydrogen. The system achieved a fairly good hydrogen production rate compared to a work reported this year, a nearly 50% increase. The intrinsic adherence of biofilms towards various interfaces allows us to grow biofilms on easy-separation micro-beads, therefore facilitating recyclable usage of the biofilm-anchored NRs and endowing this whole system with recyclability. Notably, our hydrogen production has shown great stability compared to previous reports using hydrogenase. Practically speaking, the system comprising <i>E. coli</i> and biofilms are both amenable for scalable operation, rendering itself a great potential for large-scale industrial applications. Such system can also be adapted to other energy-oriented applications by utilizing engineered new strains with a diverse spectrum of enzymes or metabolic pathways. In addition, our SpyCatcher on the CsgA allows the binding of other proteins that may significantly improve our system. The demonstrated efficiency and stability, along with great potential in scalability, recyclability and versatility makes our system an innovative engineering design with potential for industrial application. |
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<p>[*] Cao Y, Bai X F. Progress in Research of Preparation of Loaded Nano-CdS and H_2 Production by Photocatalytic Decomposition of Water[J]. Imaging Science & Photochemistry, 2009, 27(3):225-232.</p> | <p>[*] Cao Y, Bai X F. Progress in Research of Preparation of Loaded Nano-CdS and H_2 Production by Photocatalytic Decomposition of Water[J]. Imaging Science & Photochemistry, 2009, 27(3):225-232.</p> | ||
[1] Honda Y, Hagiwara H, Ida S, et al. Application to Photocatalytic H2, Production of a Whole-Cell Reaction by Recombinant Escherichia coli, Cells Expressing [FeFe]-Hydrogenase and Maturases Genes[J]. Angewandte Chemie, 2016<p></p> | [1] Honda Y, Hagiwara H, Ida S, et al. Application to Photocatalytic H2, Production of a Whole-Cell Reaction by Recombinant Escherichia coli, Cells Expressing [FeFe]-Hydrogenase and Maturases Genes[J]. Angewandte Chemie, 2016<p></p> | ||
− | [2] Z. Botyanszki, P. K. R. Tay, P. Q. Nguyen, M. G. Nussbaumer, N. S. Joshi, Engineered catalytic biofilms: Site‐specific enzyme immobilization onto E. coli curli nanofibers. Biotechnology and bioengineering 112, 2016-2024 (2015).<p></p> | + | [2] Z. Botyanszki, P. K. R. Tay, P. Q. Nguyen, M. G. Nussbaumer, N. S. Joshi, Engineered catalytic biofilms: Site‐specific enzyme immobilization onto <i>E. coli</i> curli nanofibers. Biotechnology and bioengineering 112, 2016-2024 (2015).<p></p> |
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Latest revision as of 23:09, 19 October 2016